Vol. 06, 2019
Guidelines for DNA recombination and repair studies: Mechanistic assays of DNA repair processes
Hannah L Klein1, Kenny K.H. Ang2, Michelle R. Arkin2, Emily C. Beckwitt3,4, Yi-Hsuan Chang5, Jun Fan6, Youngho Kwon7,8, Michael J. Morten1, Sucheta Mukherjee9, Oliver J. Pambos6, Hafez el Sayyed6, Elizabeth S. Thrall10, João P. Vieira-da-Rocha9, Quan Wang11, Shuang Wang12,13, Hsin-Yi Yeh5, Julie S. Biteen14, Peter Chi5,15, Wolf-Dietrich Heyer9,16, Achillefs N. Kapanidis6, Joseph J. Loparo10, Terence R. Strick12,13,17, Patrick Sung7,8, Bennett Van Houten3,18,19, Hengyao Niu11 and Eli Rothenberg1
Mechanistic assays of DNA repair processes are a powerful tools but each comes with its particular advantages and limitations. Here the most commonly used assays are reviewed, discussed, and presented as the guidelines for future studies.
Imbalance in gut microbes from babies born to obese mothers increases gut permeability and myeloid cell adaptations that provoke obesity and NAFLD
Taylor K. Soderborg1 and Jacob E. Friedman1,2,3
This article comments on work published by Soderborg et al. (Nat Commun, 2018), which demonstrates a causative role of early life microbiome dysbiosis in infants born to mothers with obesity in novel pathways that promote developmental programming of NAFLD.
Guidelines for DNA recombination and repair studies: Mechanistic assays of DNA repair processes
Hannah L Klein1, Kenny K.H. Ang2, Michelle R. Arkin2, Emily C. Beckwitt3,4, Yi-Hsuan Chang5, Jun Fan6, Youngho Kwon7,8, Michael J. Morten1, Sucheta Mukherjee9, Oliver J. Pambos6, Hafez el Sayyed6, Elizabeth S. Thrall10, João P. Vieira-da-Rocha9, Quan Wang11, Shuang Wang12,13, Hsin-Yi Yeh5, Julie S. Biteen14, Peter Chi5,15, Wolf-Dietrich Heyer9,16, Achillefs N. Kapanidis6, Joseph J. Loparo10, Terence R. Strick12,13,17, Patrick Sung7,8, Bennett Van Houten3,18,19, Hengyao Niu11 and Eli Rothenberg1
Mechanistic assays of DNA repair processes are a powerful tools but each comes with its particular advantages and limitations. Here the most commonly used assays are reviewed, discussed, and presented as the guidelines for future studies.
Imbalance in gut microbes from babies born to obese mothers increases gut permeability and myeloid cell adaptations that provoke obesity and NAFLD
Taylor K. Soderborg1 and Jacob E. Friedman1,2,3
This article comments on work published by Soderborg et al. (Nat Commun, 2018), which demonstrates a causative role of early life microbiome dysbiosis in infants born to mothers with obesity in novel pathways that promote developmental programming of NAFLD.
Adaptive bacterial response to low level chlorhexidine exposure and its implications for hand hygiene
Günter Kampf1
This article shows that bacteria can adapt to low levels of Chlorhexidine digluconate (CHG), resulting in increased tolerance and cross-resistance to other antimicrobials, suggesting caution in the widespread use of CHG to minimize avoidable selection pressure for resistance.
Microevolution of the pathogenic yeasts Candida albicans and Candida glabrata during antifungal therapy and host infection
Pedro Pais1,2,#, Mónica Galocha1,2,#, Romeu Viana1,2, Mafalda Cavalheiro1,2, Diana Pereira1,2, Miguel Cacho Teixeira1,2
This review explores how Candida albicans and Candida glabrata, common fungal pathogens resistant to antifungal therapy, adapt and evolve within different environments, aiming to identify stable adaptive mechanisms as potential drug targets.
The extracellular matrix of mycobacterial biofilms: could we shorten the treatment of mycobacterial infections?
Poushali Chakraborty1 and Ashwani Kumar1, 2
The article discusses the challenges presented by biofilms formed by non-tuberculous mycobacteria (NTM) species, which can lead to persistent infections that are difficult to treat due to phenotypic drug tolerance. The role of various cell wall components in mycobacterial biofilm formation is outlined, with a particular focus on Mycobacterium tuberculosis.
Guidelines for DNA recombination and repair studies: Cellular assays of DNA repair pathways
Hannah L. Klein1, Giedrė Bačinskaja2, Jun Che3, Anais Cheblal4, Rajula Elango5, Anastasiya Epshtein1, Devon M. Fitzgerald6-9, Belén Gómez-González10, Sharik R. Khan11, Sandeep Kumar7, Bryan A. Leland12, Léa Marie13, Qian Mei14, Judith Miné-Hattab16,17, Alicja Piotrowska18, Erica J. Polleys19, Christopher D. Putnam20,21, Elina A. Radchenko19, Anissia Ait Saada22,23, Cynthia J. Sakofsky24, Eun Yong Shim3, Mathew Stracy25, Jun Xia6-9, Zhenxin Yan7, Yi Yin26, Andrés Aguilera10, Juan Lucas Argueso27, Catherine H. Freudenreich19,28, Susan M. Gasser4, Dmitry A. Gordenin24, James E. Haber29, Grzegorz Ira7, Sue Jinks-Robertson30, Megan C. King12, Richard D. Kolodner20, 31-33, Andrei Kuzminov11, Sarah AE Lambert22,23, Sang Eun Lee3, Kyle M. Miller6,15, Sergei M. Mirkin19, Thomas D. Petes26, Susan M. Rosenberg6-9,14, Rodney Rothstein34, Lorraine S. Symington13, Pawel Zawadzki18, Nayun Kim35, Michael Lisby2 and Anna Malkova5
DNA recombination, repair and mutagenesis assays are powerful tools but each comes with its particular advantages and limitations. Here the most commonly used assays are reviewed, discussed, and presented as the guidelines for future studies.
Guidelines for DNA recombination and repair studies: Mechanistic assays of DNA repair processes
Hannah L Klein1, Kenny K.H. Ang2, Michelle R. Arkin2, Emily C. Beckwitt3,4, Yi-Hsuan Chang5, Jun Fan6, Youngho Kwon7,8, Michael J. Morten1, Sucheta Mukherjee9, Oliver J. Pambos6, Hafez el Sayyed6, Elizabeth S. Thrall10, João P. Vieira-da-Rocha9, Quan Wang11, Shuang Wang12,13, Hsin-Yi Yeh5, Julie S. Biteen14, Peter Chi5,15, Wolf-Dietrich Heyer9,16, Achillefs N. Kapanidis6, Joseph J. Loparo10, Terence R. Strick12,13,17, Patrick Sung7,8, Bennett Van Houten3,18,19, Hengyao Niu11 and Eli Rothenberg1
Mechanistic assays of DNA repair processes are a powerful tools but each comes with its particular advantages and limitations. Here the most commonly used assays are reviewed, discussed, and presented as the guidelines for future studies.
Imbalance in gut microbes from babies born to obese mothers increases gut permeability and myeloid cell adaptations that provoke obesity and NAFLD
Taylor K. Soderborg1 and Jacob E. Friedman1,2,3
This article comments on work published by Soderborg et al. (Nat Commun, 2018), which demonstrates a causative role of early life microbiome dysbiosis in infants born to mothers with obesity in novel pathways that promote developmental programming of NAFLD.
Targeting GATA transcription factors – a novel strategy for anti-aging interventions?
Andreas Zimmermann1, Katharina Kainz1,2, Sebastian J. Hofer1,3, Maria A. Bauer1, Sabrina Schroeder1, Jörn Dengjel4, Federico Pietrocola5, Oliver Kepp6-9, Christoph Ruckenstuhl1, Tobias Eisenberg1,3,10,11, Stephan J. Sigrist12, Frank Madeo1,3,10, Guido Kroemer6-9, 13-15 and Didac Carmona-Gutierrez1
This article comments on work published by Carmona-Gutierrez et al. (Nat Commun., 2019), which identified a natural compound, 4,4'-dimethoxychalcone, inducing autophagy and prolonging lifespan in different organisms through a mechanism that involves GATA transcription factors.
In the beginning was the word: How terminology drives our understanding of endosymbiotic organelles
Miroslav Oborník 1,2
This In the Pit article argues that the naming conventions for biological entities influence research perspectives and methodologies, advocating for mitochondria and plastids to be classified and named as bacteria due to their endosymbiotic origins, with potential implications for our understanding of bacterial prevalence, definitions of the microbiome and multicellularity, and the concept of endosymbiotic domestication.
What’s in a name? How organelles of endosymbiotic origin can be distinguished from endosymbionts
Ansgar Gruber1
This In the Pit article suggests redefining the relationship between hosts and endosymbionts, like mitochondria and plastids, as a single species based on "sexual symbiont integration," the loss of independent speciation, and congruence in genetic recombination and population sizes, rather than solely on historic classifications or structural properties.
Sulfur dioxide resistance in Saccharomyces cerevisiae: beyond SSU1
November 21, 2019
This article discusses the importance of understanding sulfite resistance in Saccharomyces cerevisiae due to its use in winemaking and the potential role of the transcription factor Com2. While the SSU1 gene and its activity have been correlated with sulfite tolerance, the work by Lage et al. (2019) indicates that Com2 might control a large percentage of the genes activated by SO2 and contribute to the yeast's protective response, offering new insights into the molecular factors influencing this oenological trait.
Metabolic reprogramming of Salmonella infected macrophages and its modulation by iron availability and the mTOR pathway
November 14, 2019
This article shows that iron plays a critical role in both the immune response and metabolic reprogramming of macrophages during infection, influencing the TCA cycle and mTOR pathway, with implications for the growth of intracellular bacteria like Salmonella.
Tribal warfare: Commensal Neisseria kill pathogen Neisseria gonorrhoeae using its DNA
October 19, 2019
This article comments on work published by Kim et al (Cell Host Microbe, 2019), which adds a new dimension to the concept of commensal protection. It shows that commensal Neisseria kill the closely related pathogen N. gonorrhoeae through an unexpected mechanism, one that involves genetic competence, DNA methylation state and recombination.
Yet another job for the bacterial ribosome
October 17, 2019
This article comments on work published by Knüpffer et al (mBio, 2019), which revealed the intricate interaction of uL23 with yet another essential player in bacteria, the ATPase SecA, which is best known for its role during post-translational secretion of proteins across the bacterial SecYEG translocon
Transcriptomic and chemogenomic analyses unveil the essential role of Com2-regulon in response and tolerance of Saccharomyces cerevisiae to stress induced by sulfur dioxide
September 30, 2019
This article shows that in the presence of sulfur dioxide (SO2), the transcription factor Com2 plays a critical role in the tolerance and response of Saccharomyces cerevisiae, affecting the expression of a majority of SO2-activated genes and contributing to the protection against stress induced by SO2 at an enologically relevant pH.
Gut microbial metabolites in depression: understanding the biochemical mechanisms
September 27, 2019
This article shows how the gut microbiota contributes to the pathophysiology of depression and examines the mechanisms by which microbially-derived molecules may influence depressive behavior, highlighting the potential of dietary interventions as novel therapeutic strategies.
The multiple functions of the numerous Chlamydia trachomatis secreted proteins: the tip of the iceberg
August 21, 2019
CThis article shows an in-depth review on the current knowledge and outstanding questions about secreted proteins from Chlamydia trachomatis, detailing their roles in host cell interaction and immune response evasion.
Inhibiting eukaryotic ribosome biogenesis: Mining new tools for basic research and medical applications
August 20, 2019
This article comments on work published by Awad et al (BMC Biology, 2019), which screened for novel inhibitors of the ribosome biogenesis pathway in yeast.
Sulfur dioxide resistance in Saccharomyces cerevisiae: beyond SSU1
Estéfani García-Ríos1 and José Manuel Guillamón1
This article discusses the importance of understanding sulfite resistance in Saccharomyces cerevisiae due to its use in winemaking and the potential role of the transcription factor Com2. While the SSU1 gene and its activity have been correlated with sulfite tolerance, the work by Lage et al. (2019) indicates that Com2 might control a large percentage of the genes activated by SO2 and contribute to the yeast's protective response, offering new insights into the molecular factors influencing this oenological trait.