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Nature Biotechnology

Resumen/Descripción – provisto por la editorial en inglés
Nature Biotechnology is a monthly journal covering the science and business of biotechnology. It publishes new concepts in technology/methodology of relevance to the biological, biomedical, agricultural and environmental sciences as well as covers the commercial, political, ethical, legal, and societal aspects of this research. The first function is fulfilled by the peer-reviewed research section, the second by the expository efforts in the front of the journal. We provide researchers with news about business; we provide the business community with news about research developments.
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Disponibilidad
Institución detectada Período Navegá Descargá Solicitá
No detectada desde jul. 2012 / hasta dic. 2023 Nature.com

Información

Tipo de recurso:

revistas

ISSN impreso

1087-0156

ISSN electrónico

1546-1696

Editor responsable

Springer Nature

País de edición

Reino Unido

Fecha de publicación

Tabla de contenidos

Predicting prime editing efficiency and product purity by deep learning

Nicolas MathisORCID; Ahmed AllamORCID; Lucas KisslingORCID; Kim Fabiano MarquartORCID; Lukas SchmidheiniORCID; Cristina Solari; Zsolt Balázs; Michael KrauthammerORCID; Gerald SchwankORCID

Palabras clave: Biomedical Engineering; Molecular Medicine; Applied Microbiology and Biotechnology; Bioengineering; Biotechnology.

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Author Correction: A spatial genome aligner for resolving chromatin architectures from multiplexed DNA FISH

Bojing Blair Jia; Adam Jussila; Colin Kern; Quan Zhu; Bing RenORCID

Palabras clave: Biomedical Engineering; Molecular Medicine; Applied Microbiology and Biotechnology; Bioengineering; Biotechnology.

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Engineered live bacteria suppress Pseudomonas aeruginosa infection in mouse lung and dissolve endotracheal-tube biofilms

Rocco Mazzolini; Irene Rodríguez-Arce; Laia Fernández-BaratORCID; Carlos Piñero-LambeaORCID; Victoria GarridoORCID; Agustín Rebollada-MerinoORCID; Anna Motos; Antoni TorresORCID; Maria Jesús GrillóORCID; Luis SerranoORCID; Maria Lluch-SenarORCID

<jats:title>Abstract</jats:title><jats:p>Engineered live bacteria could provide a new modality for treating lung infections, a major cause of mortality worldwide. In the present study, we engineered a genome-reduced human lung bacterium, <jats:italic>Mycoplasma pneumoniae</jats:italic>, to treat ventilator-associated pneumonia, a disease with high hospital mortality when associated with <jats:italic>Pseudomonas aeruginosa</jats:italic> biofilms. After validating the biosafety of an attenuated <jats:italic>M. pneumoniae</jats:italic> chassis in mice, we introduced four transgenes into the chromosome by transposition to implement bactericidal and biofilm degradation activities. We show that this engineered strain has high efficacy against an acute <jats:italic>P. aeruginosa</jats:italic> lung infection in a mouse model. In addition, we demonstrated that the engineered strain could dissolve biofilms formed in endotracheal tubes of patients with ventilator-associated pneumonia and be combined with antibiotics targeting the peptidoglycan layer to increase efficacy against Gram-positive and Gram-negative bacteria. We expect our <jats:italic>M. pneumoniae</jats:italic>-engineered strain to be able to treat biofilm-associated infections in the respiratory tract.</jats:p>

Palabras clave: Biomedical Engineering; Molecular Medicine; Applied Microbiology and Biotechnology; Bioengineering; Biotechnology.

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Genome-scale metabolic reconstruction of 7,302 human microorganisms for personalized medicine

Almut HeinkenORCID; Johannes Hertel; Geeta Acharya; Dmitry A. Ravcheev; Malgorzata Nyga; Onyedika Emmanuel OkpalaORCID; Marcus Hogan; Stefanía MagnúsdóttirORCID; Filippo Martinelli; Bram Nap; German PreciatORCID; Janaka N. Edirisinghe; Christopher S. Henry; Ronan M. T. Fleming; Ines ThieleORCID

<jats:title>Abstract</jats:title><jats:p>The human microbiome influences the efficacy and safety of a wide variety of commonly prescribed drugs. Designing precision medicine approaches that incorporate microbial metabolism would require strain- and molecule-resolved, scalable computational modeling. Here, we extend our previous resource of genome-scale metabolic reconstructions of human gut microorganisms with a greatly expanded version. AGORA2 (assembly of gut organisms through reconstruction and analysis, version 2) accounts for 7,302 strains, includes strain-resolved drug degradation and biotransformation capabilities for 98 drugs, and was extensively curated based on comparative genomics and literature searches. The microbial reconstructions performed very well against three independently assembled experimental datasets with an accuracy of 0.72 to 0.84, surpassing other reconstruction resources and predicted known microbial drug transformations with an accuracy of 0.81. We demonstrate that AGORA2 enables personalized, strain-resolved modeling by predicting the drug conversion potential of the gut microbiomes from 616 patients with colorectal cancer and controls, which greatly varied between individuals and correlated with age, sex, body mass index and disease stages. AGORA2 serves as a knowledge base for the human microbiome and paves the way to personalized, predictive analysis of host–microbiome metabolic interactions.</jats:p>

Palabras clave: Biomedical Engineering; Molecular Medicine; Applied Microbiology and Biotechnology; Bioengineering; Biotechnology.

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Precision targeting of autoantigen-specific B cells in muscle-specific tyrosine kinase myasthenia gravis with chimeric autoantibody receptor T cells

Sangwook OhORCID; Xuming MaoORCID; Silvio Manfredo-VieiraORCID; Jinmin Lee; Darshil Patel; Eun Jung Choi; Andrea Alvarado; Ebony Cottman-Thomas; Damian MasedaORCID; Patricia Y. TsaoORCID; Christoph T. Ellebrecht; Sami L. Khella; David P. Richman; Kevin C. O’ConnorORCID; Uri Herzberg; Gwendolyn K. Binder; Michael C. Milone; Samik Basu; Aimee S. PayneORCID

<jats:title>Abstract</jats:title><jats:p>Muscle-specific tyrosine kinase myasthenia gravis (MuSK MG) is an autoimmune disease that causes life-threatening muscle weakness due to anti-MuSK autoantibodies that disrupt neuromuscular junction signaling. To avoid chronic immunosuppression from current therapies, we engineered T cells to express a MuSK chimeric autoantibody receptor with CD137-CD3ζ signaling domains (MuSK-CAART) for precision targeting of B cells expressing anti-MuSK autoantibodies. MuSK-CAART demonstrated similar efficacy as anti-CD19 chimeric antigen receptor T cells for depletion of anti-MuSK B cells and retained cytolytic activity in the presence of soluble anti-MuSK antibodies. In an experimental autoimmune MG mouse model, MuSK-CAART reduced anti-MuSK IgG without decreasing B cells or total IgG levels, reflecting MuSK-specific B cell depletion. Specific off-target interactions of MuSK-CAART were not identified in vivo, in primary human cell screens or by high-throughput human membrane proteome array. These data contributed to an investigational new drug application and phase 1 clinical study design for MuSK-CAART for the treatment of MuSK autoantibody-positive MG.</jats:p>

Palabras clave: Biomedical Engineering; Molecular Medicine; Applied Microbiology and Biotechnology; Bioengineering; Biotechnology.

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Chem-map profiles drug binding to chromatin in cells

Zutao Yu; Jochen SpiegelORCID; Larry Melidis; Winnie W. I. HuiORCID; Xiaoyun ZhangORCID; Antanas RadzevičiusORCID; Shankar BalasubramanianORCID

<jats:title>Abstract</jats:title><jats:p>Characterizing drug–target engagement is essential to understand how small molecules influence cellular functions. Here we present Chem-map for in situ mapping of small molecules that interact with DNA or chromatin-associated proteins, utilizing small-molecule-directed transposase Tn5 tagmentation. We demonstrate Chem-map for three distinct drug-binding modalities as follows: molecules that target a chromatin protein, a DNA secondary structure or that intercalate in DNA. We map the BET bromodomain protein-binding inhibitor JQ1 and provide interaction maps for DNA G-quadruplex structure-binding molecules PDS and PhenDC3. Moreover, we determine the binding sites of the widely used anticancer drug doxorubicin in human leukemia cells; using the Chem-map of doxorubicin in cells exposed to the histone deacetylase inhibitor tucidinostat reveals the potential clinical advantages of this combination therapy. In situ mapping with Chem-map of small-molecule interactions with DNA and chromatin proteins provides insights that will enhance understanding of genome and chromatin function and therapeutic interventions.</jats:p>

Palabras clave: Biomedical Engineering; Molecular Medicine; Applied Microbiology and Biotechnology; Bioengineering; Biotechnology.

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Precise transcript targeting by CRISPR-Csm complexes

David ColognoriORCID; Marena Trinidad; Jennifer A. DoudnaORCID

<jats:title>Abstract</jats:title><jats:p>Robust and precise transcript targeting in mammalian cells remains a difficult challenge using existing approaches due to inefficiency, imprecision and subcellular compartmentalization. Here we show that the clustered regularly interspaced short palindromic repeats (CRISPR)-Csm complex, a multiprotein effector from type III CRISPR immune systems in prokaryotes, provides surgical RNA ablation of both nuclear and cytoplasmic transcripts. As part of the most widely occurring CRISPR adaptive immune pathway, CRISPR-Csm uses a programmable RNA-guided mechanism to find and degrade target RNA molecules without inducing indiscriminate <jats:italic>trans</jats:italic>-cleavage of cellular RNAs, giving it an important advantage over the CRISPR-Cas13 family of enzymes. Using single-vector delivery of the <jats:italic>Streptococcus thermophilus</jats:italic> Csm complex, we observe high-efficiency RNA knockdown (90–99%) and minimal off-target effects in human cells, outperforming existing technologies including short hairpin RNA- and Cas13-mediated knockdown. We also find that catalytically inactivated Csm achieves specific and durable RNA binding, a property we harness for live-cell RNA imaging. These results establish the feasibility and efficacy of multiprotein CRISPR-Cas effector complexes as RNA-targeting tools in eukaryotes.</jats:p>

Palabras clave: Biomedical Engineering; Molecular Medicine; Applied Microbiology and Biotechnology; Bioengineering; Biotechnology.

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CRISPR-Csm for eukaryotic RNA knockdown and imaging without toxicity

Palabras clave: Biomedical Engineering; Molecular Medicine; Applied Microbiology and Biotechnology; Bioengineering; Biotechnology.

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Large language models generate functional protein sequences across diverse families

Ali MadaniORCID; Ben Krause; Eric R. Greene; Subu Subramanian; Benjamin P. Mohr; James M. HoltonORCID; Jose Luis Olmos; Caiming Xiong; Zachary Z. Sun; Richard Socher; James S. Fraser; Nikhil NaikORCID

Palabras clave: Biomedical Engineering; Molecular Medicine; Applied Microbiology and Biotechnology; Bioengineering; Biotechnology.

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In vivo development of immune tissue in human intestinal organoids transplanted into humanized mice

Carine Bouffi; Kathryn A. Wikenheiser-Brokamp; Praneet Chaturvedi; Nambirajan Sundaram; Gillian R. Goddard; Mark Wunderlich; Nicole E. Brown; Janet F. Staab; Rachel Latanich; Nicholas C. Zachos; Emily M. Holloway; Maxime M. MaheORCID; Holly M. Poling; Simon Vales; Garrett W. Fisher; Jason R. Spence; James C. Mulloy; Aaron M. Zorn; James M. WellsORCID; Michael A. HelmrathORCID

<jats:title>Abstract</jats:title><jats:p>Human intestinal organoids (HIOs) derived from pluripotent stem cells provide a valuable model for investigating human intestinal organogenesis and physiology, but they lack the immune components required to fully recapitulate the complexity of human intestinal biology and diseases. To address this issue and to begin to decipher human intestinal–immune crosstalk during development, we generated HIOs containing immune cells by transplanting HIOs under the kidney capsule of mice with a humanized immune system. We found that human immune cells temporally migrate to the mucosa and form cellular aggregates that resemble human intestinal lymphoid follicles. Moreover, after microbial exposure, epithelial microfold cells are increased in number, leading to immune cell activation determined by the secretion of IgA antibodies in the HIO lumen. This in vivo HIO system with human immune cells provides a framework for future studies on infection- or allergen-driven intestinal diseases.</jats:p>

Palabras clave: Biomedical Engineering; Molecular Medicine; Applied Microbiology and Biotechnology; Bioengineering; Biotechnology.

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