Your search keyword '"Paola A. Mancera"' showing total 7 results

1. Diels-Alder reaction mechanisms of substituted chiral anthracene: A theoretical study based on the reaction force and reaction electronic flux.

Author

Jennifer Paola Hernández Mancera, Francisco Núñez-Zarur, Soledad Gutiérrez-Oliva, Alejandro Toro-Labbé, and Ricardo Vivas-Reyes

Published

2020

2. Digging on the Mechanism of Some Diels-Alder Reactions. The Role of the Reaction Electronic Flux

Author

Jennifer Paola Hernández-Mancera, Ricardo Vivas-Reyes, Soledad Gutiérrez-Oliva, Barbara Herrera, and Alejandro Toro-Labbé

Abstract

Within the framework of the reaction force analysis, the Marcus Potential Energy Function as well as the Activation Strain Model are characterized and used to rationalize the energetics of some representative Diels-Alder reactions involving three substituted furandione as dienophile, and a chiral anthracene, as diene. The analysis of reaction barriers indicates that the activation process of the reactions is dominated by the structural rearrangements of reactants which are mainly driven by the approach of diene to the dienophile. On the other hand, the electronic activity taking place along the reaction coordinate have been analyzed through the reaction electronic flux. It has been found that the electronic activity that emerge more intensively within the transition state region, is mainly due to electronic transfer effects, due to the breaking and forming π bonds. Although polarization is also present but to a lesser extent.

Published

2023

3. Genomes of ubiquitous marine and hypersaline Hydrogenovibrio , Thiomicrorhabdus and Thiomicrospira spp. encode a diversity of mechanisms to sustain chemolithoautotrophy in heterogeneous environments

Author

Cheryl A. Kerfeld, Eva Chase, Jason C. Richardson, Tara L. Harmer, Chris Daum, Emily A. McIntyre, Nicole Shapiro, Kaleigh M. Nelson, Darren S. Dunlap, Brittney D. Moore, Manoj Pillay, Kimmy N. Nguyen, Marcel Huntemann, Neha Varghese, Maki Tabuchi, Christie K. Campla, Michael R. Solone, John Williams, Natalia Ivanova, Rich Boden, Alicia Clum, Zachery R. Staley, William A. Morgan, Elizabeth M. Fahsbender, T. B. K. Reddy, Courtney Lewis, Dawn B. Goldsmith, Gary J. Camper, Christina M. Rodgers, Dimitrios Stamatis, Jessica A. Mine, David G. Parrino, Leila G. Casella, Pauline Wanjugi, Brent L. Schaffer, Elizabeth A. Rampersad, Suzanne Young, Ryan Keeley, Anangamanjari D. Pedapudi, Breanna I. Kussy, Stephanie Lawler, Cody M. B. Porter, Kathleen M. Scott, John H. Paul, Nancy E. Sheridan, Nicholas Ogburn, Paola A. Mancera, James W. Conrad, Nikos C. Kyrpides, Ramond J. Waide, Rebecca P. Pelham, Tanja Woyke, Mercedez C. Cruz, Krishnaveni Palaniappan, Matthew R. Kondoff, Sydney Russel, Sharyn K. Freyermuth, Evan C. McClenthan, Brittany Leigh, Natalia Mikhailova, Swapnil Modi, Amanda M. Preece, Lygia M. Lostal, Devon Marking, Megan K. Bridges, Laura Duran, Kirsten M. Antonen, and Marannda K. Lane

Subjects

0301 basic medicine, Cytochrome, Operon, 030106 microbiology, Biology, biology.organism_classification, Microbiology, Genome, 03 medical and health sciences, Carboxysome, 030104 developmental biology, Evolutionary biology, Horizontal gene transfer, Gammaproteobacteria, biology.protein, Cytochrome c oxidase, Gene, Ecology, Evolution, Behavior and Systematics

Abstract

Chemolithoautotrophic bacteria from the genera Hydrogenovibrio, Thiomicrorhabdus and Thiomicrospira are common, sometimes dominant, isolates from sulfidic habitats including hydrothermal vents, soda and salt lakes and marine sediments. Their genome sequences confirm their membership in a deeply branching clade of the Gammaproteobacteria. Several adaptations to heterogeneous habitats are apparent. Their genomes include large numbers of genes for sensing and responding to their environment (EAL- and GGDEF-domain proteins and methyl-accepting chemotaxis proteins) despite their small sizes (2.1-3.1 Mbp). An array of sulfur-oxidizing complexes are encoded, likely to facilitate these organisms' use of multiple forms of reduced sulfur as electron donors. Hydrogenase genes are present in some taxa, including group 1d and 2b hydrogenases in Hydrogenovibrio marinus and H. thermophilus MA2-6, acquired via horizontal gene transfer. In addition to high-affinity cbb3 cytochrome c oxidase, some also encode cytochrome bd-type quinol oxidase or ba3 -type cytochrome c oxidase, which could facilitate growth under different oxygen tensions, or maintain redox balance. Carboxysome operons are present in most, with genes downstream encoding transporters from four evolutionarily distinct families, which may act with the carboxysomes to form CO2 concentrating mechanisms. These adaptations to habitat variability likely contribute to the cosmopolitan distribution of these organisms.

Published

2018

4. ANÁLISIS TEÓRICO DE REACTIVIDAD Y MECANISMOS DE REACCIÓN DIELS-ALDER DE UN ANTRACENO QUIRAL CON DIENÓFILOS SIMÉTRICOS Y ASIMÉTRICOS

Author

Paola Hernandez Mancera, Jennifer, primary, Nuñez Zarur, Francisco, primary, Toro Labbé, Alejandro, primary, and Vivas Reyes, Ricardo, primary

Published

2020

5. Degenerate PCR primers for assays to track steps of nitrogen metabolism by taxonomically diverse microorganisms in a variety of environments

Author

Gemma E. Briggs, U.S.F. Genomics Class, Paola A. Mancera, Ryan Keeley, Kathleen M. Scott, Victoria E. Frazier, Haider S. Manzer, Laura C. Rodriguez-Gonzalez, and Sarina J. Ergas

Subjects

DNA, Bacterial, Microbiology (medical), Nitrite Reductases, Nitrogen, Wastewater, Polymerase Chain Reaction, Microbiology, 03 medical and health sciences, Denitrifying bacteria, chemistry.chemical_compound, Molecular Biology, Betaproteobacteria, DNA Primers, 030304 developmental biology, 0303 health sciences, Bacteria, biology, 030306 microbiology, Comammox, Amplicon, Ammonia monooxygenase, biology.organism_classification, Nitrification, 6. Clean water, Biochemistry, Nitrite oxidoreductase, chemistry, GenBank, Proteobacteria, Oxidoreductases, Water Microbiology

Abstract

Steps in the global nitrogen cycle are mainly catalyzed by microorganisms. Accordingly, the activities of these microorganisms affect the health and productivity of ecosystems. Their activities are also used in wastewater treatment systems to remove reactive nitrogen compounds and prevent eutrophication events triggered by nutrient discharges. Therefore, tracking the activities of these microorganisms can provide insights into the functioning of these systems. The presence and abundance of genes encoding nitrogen-metabolizing enzymes can be traced via polymerase chain reaction (PCR); however, this requires primers that are sensitive to a heterogenous gene pool yet specific enough to the target biomarker. The ever-expanding diversity of sequences available from databases includes many sequences relevant to nitrogen metabolism that match poorly with primers previously designed to track their presence and/or abundance. This includes genes encoding ammonia monooxygenase (AMO) of ammonia oxidizing microorganisms, nitrite oxidoreductase (NXR) of nitrite oxidizing bacteria, and nitrous oxide reductase (NOS) of denitrifying bacteria. Some primers are also not designed to generate the short (~200 nucleotides) amplicons required for real-time quantitative PCR (qPCR) and reverse-transcriptase qPCR (qRT-PCR). In this study, genes collected from the Integrated Microbial Genomes database (IMG) were aligned to design PCR primers that could capture more sequence diversity than is possible using existing primers. Primers were designed to target three clades of AMO (Betaproteobacteria, Chrenarchaeota, and complete ammonia oxidizing Nitrospira), periplasmic NXR and two clades of NOS (Proteobacteria and Bacteroidetes/Firmicutes). These primers successfully amplified target sequences from two wastewater treatment plants with biological nitrogen removal (one with simultaneous nitrification/denitrification and one with distinct anoxic/oxic zones) and estuary sediment. Nucleotide sequences of the amplicons retrieved homologs when used to query GenBank by BLAST. While convincingly identified as target sequences for these primer pairs, these amplicons were divergent from each other, and quite divergent (as low as 73%) from those present in GenBank, suggesting these primers are capable of capturing a diverse range of sequences. A direct comparison showed that primers designed here are better suited to environmental samples, such as wastewater treatment facilities, by producing a greater number of amplicons from the same sample than primers currently established in literature.

Published

2020

6. Genomes of ubiquitous marine and hypersaline Hydrogenovibrio, Thiomicrorhabdus and Thiomicrospira spp. encode a diversity of mechanisms to sustain chemolithoautotrophy in heterogeneous environments

Author

Kathleen M, Scott, John, Williams, Cody M B, Porter, Sydney, Russel, Tara L, Harmer, John H, Paul, Kirsten M, Antonen, Megan K, Bridges, Gary J, Camper, Christie K, Campla, Leila G, Casella, Eva, Chase, James W, Conrad, Mercedez C, Cruz, Darren S, Dunlap, Laura, Duran, Elizabeth M, Fahsbender, Dawn B, Goldsmith, Ryan F, Keeley, Matthew R, Kondoff, Breanna I, Kussy, Marannda K, Lane, Stephanie, Lawler, Brittany A, Leigh, Courtney, Lewis, Lygia M, Lostal, Devon, Marking, Paola A, Mancera, Evan C, McClenthan, Emily A, McIntyre, Jessica A, Mine, Swapnil, Modi, Brittney D, Moore, William A, Morgan, Kaleigh M, Nelson, Kimmy N, Nguyen, Nicholas, Ogburn, David G, Parrino, Anangamanjari D, Pedapudi, Rebecca P, Pelham, Amanda M, Preece, Elizabeth A, Rampersad, Jason C, Richardson, Christina M, Rodgers, Brent L, Schaffer, Nancy E, Sheridan, Michael R, Solone, Zachery R, Staley, Maki, Tabuchi, Ramond J, Waide, Pauline W, Wanjugi, Suzanne, Young, Alicia, Clum, Chris, Daum, Marcel, Huntemann, Natalia, Ivanova, Nikos, Kyrpides, Natalia, Mikhailova, Krishnaveni, Palaniappan, Manoj, Pillay, T B K, Reddy, Nicole, Shapiro, Dimitrios, Stamatis, Neha, Varghese, Tanja, Woyke, Rich, Boden, Sharyn K, Freyermuth, and Cheryl A, Kerfeld

Subjects

Chemoautotrophic Growth, Hydrogenase, Piscirickettsiaceae, Ecosystem, Genome, Bacterial, Phylogeny, Sulfur

Abstract

Chemolithoautotrophic bacteria from the genera Hydrogenovibrio, Thiomicrorhabdus and Thiomicrospira are common, sometimes dominant, isolates from sulfidic habitats including hydrothermal vents, soda and salt lakes and marine sediments. Their genome sequences confirm their membership in a deeply branching clade of the Gammaproteobacteria. Several adaptations to heterogeneous habitats are apparent. Their genomes include large numbers of genes for sensing and responding to their environment (EAL- and GGDEF-domain proteins and methyl-accepting chemotaxis proteins) despite their small sizes (2.1-3.1 Mbp). An array of sulfur-oxidizing complexes are encoded, likely to facilitate these organisms' use of multiple forms of reduced sulfur as electron donors. Hydrogenase genes are present in some taxa, including group 1d and 2b hydrogenases in Hydrogenovibrio marinus and H. thermophilus MA2-6, acquired via horizontal gene transfer. In addition to high-affinity cbb

Published

2017

7. Proteomic and Mutant Analysis of the CO 2 Concentrating Mechanism of Hydrothermal Vent Chemolithoautotroph Thiomicrospira crunogena

Author

Chongle Pan, Dale Chaput, Stanley M. Stevens, David A. Nicholson, Pauline Wanjugi, Mary Mangiapia, Juliana M. Leonard, Kathleen M. Scott, Ryan Keeley, Paola A. Mancera, Edward M Haller, Terry‐René W. Brown, Zahra Hashemy, Tania Zabinski, and Tara L. Harmer

Subjects

0301 basic medicine, biology, Carbon fixation, Bicarbonate transporter protein, biology.organism_classification, Microbiology, 03 medical and health sciences, Carboxysome, 030104 developmental biology, Biochemistry, Autotroph, Euryarchaeota, Molecular Biology, Bacteria, Archaea, Thiomicrospira crunogena

Abstract

Many autotrophic microorganisms are likely to adapt to scarcity in dissolved inorganic carbon (DIC; CO 2 + HCO 3 − + CO 3 2− ) with CO 2 concentrating mechanisms (CCM) that actively transport DIC across the cell membrane to facilitate carbon fixation. Surprisingly, DIC transport has been well studied among cyanobacteria and microalgae only. The deep-sea vent gammaproteobacterial chemolithoautotroph Thiomicrospira crunogena has a low-DIC inducible CCM, though the mechanism for uptake is unclear, as homologs to cyanobacterial transporters are absent. To identify the components of this CCM, proteomes of T. crunogena cultivated under low- and high-DIC conditions were compared. Fourteen proteins, including those comprising carboxysomes, were at least 4-fold more abundant under low-DIC conditions. One of these proteins was encoded by Tcr_0854 ; strains carrying mutated copies of this gene, as well as the adjacent Tcr_0853 , required elevated DIC for growth. Strains carrying mutated copies of Tcr_0853 and Tcr_0854 overexpressed carboxysomes and had diminished ability to accumulate intracellular DIC. Based on reverse transcription (RT)-PCR, Tcr_0853 and Tcr_0854 were cotranscribed and upregulated under low-DIC conditions. The Tcr_0853 -encoded protein was predicted to have 13 transmembrane helices. Given the mutant phenotypes described above, Tcr_0853 and Tcr_0854 may encode a two-subunit DIC transporter that belongs to a previously undescribed transporter family, though it is widespread among autotrophs from multiple phyla. IMPORTANCE DIC uptake and fixation by autotrophs are the primary input of inorganic carbon into the biosphere. The mechanism for dissolved inorganic carbon uptake has been characterized only for cyanobacteria despite the importance of DIC uptake by autotrophic microorganisms from many phyla among the Bacteria and Archaea . In this work, proteins necessary for dissolved inorganic carbon utilization in the deep-sea vent chemolithoautotroph T. crunogena were identified, and two of these may be able to form a novel transporter. Homologs of these proteins are present in 14 phyla in Bacteria and also in one phylum of Archaea , the Euryarchaeota . Many organisms carrying these homologs are autotrophs, suggesting a role in facilitating dissolved inorganic carbon uptake and fixation well beyond the genus Thiomicrospira .

Published

2017