Your search keyword '"Jin, Xiaofan"' showing total 6 results

1. Optogenetic patterning generates multi-strain biofilms with spatially distributed antibiotic resistance.

Author

Jin, Xiaofan and Riedel-Kruse, Ingmar H.

Subjects

BIOTIC communities, DIVISION of labor, DRUG resistance in bacteria, CELL aggregation, AMPICILLIN, BIOFILMS

Abstract

Spatial organization of microbes in biofilms enables crucial community function such as division of labor. However, quantitative understanding of such emergent community properties remains limited due to a scarcity of tools for patterning heterogeneous biofilms. Here we develop a synthetic optogenetic toolkit 'Multipattern Biofilm Lithography' for rational engineering and orthogonal patterning of multi-strain biofilms, inspired by successive adhesion and phenotypic differentiation in natural biofilms. We apply this toolkit to profile the growth dynamics of heterogeneous biofilm communities, and observe the emergence of spatially modulated commensal relationships due to shared antibiotic protection against the beta-lactam ampicillin. Supported by biophysical modeling, these results yield in-vivo measurements of key parameters, e.g., molecular beta-lactamase production per cell and length scale of antibiotic zone of protection. Our toolbox and associated findings provide quantitative insights into the spatial organization and distributed antibiotic protection within biofilms, with direct implications for future biofilm research and engineering. In natural biofilm communities, bacterial spatial organization increases functional complexity. Here, authors present a synthetic biofilm toolkit that patterns distinct cell types with arbitrary spatial organization, and demonstrate how this organization can enable sharing of antibiotic protection. [ABSTRACT FROM AUTHOR]

Published

2024

2. Brij-58 supplementation enhances menaquinone-7 biosynthesis and secretion in Bacillus natto.

Author

Yi, Yunxin, Jin, Xiaofan, Chen, Moutong, Coldea, Teodora Emilia, Yang, Huirong, and Zhao, Haifeng

Subjects

*BACILLUS (Bacteria), *SECRETION, *BIOSURFACTANTS, *BIOSYNTHESIS, *DIETARY supplements, *INTERFACIAL tension

Abstract

Menaquinone-7 is a form of vitamin K2 that has been shown to have numerous healthy benefits. In this study, several surfactants were investigated to enhance the production of menaquinone-7 in Bacillus natto. Results showed that Brij-58 supplementation influenced the cell membrane via adsorption, and changed the interfacial tension of fermentation broth, while the changes in the state and the composition of the cell membrane enhanced the secretion and biosynthesis of menaquinone-7. The total production and secretion rate of menaquinone-7 increased by 48.0% and 56.2% respectively. During fermentation, the integrity of the cell membrane decreased by 82.9% while the permeability increased by 158% when the maximum secretory rate was reached. Furthermore, Brij-58 supplementation induced the stress response in bacteria, resulting in hyperpolarization of the membrane, and increased membrane ATPase activity. Finally, changes in fatty acid composition increased membrane fluidity by 30.1%. This study provided an effective strategy to enhance menaquinone-7 yield in Bacillus natto and revealed the mechanism of Brij-58 supplementation in menaquinone-7 production. Key points: • MK-7 yield in Bacillus natto was significantly increased by Brij-58 supplementation. • Brij-58 could be adsorbed on cell surface and change fermentation environment. • Brij-58 supplementation could affect the state and composition of the cell membrane. [ABSTRACT FROM AUTHOR]

Published

2023

3. Culturing of a complex gut microbial community in mucin-hydrogel carriers reveals strain- and gene-associated spatial organization.

Author

Jin, Xiaofan, Yu, Feiqiao B., Yan, Jia, Weakley, Allison M., Dubinkina, Veronika, Meng, Xiandong, and Pollard, Katherine S.

Subjects

MICROBIAL communities, MICROBIAL genes, BACTERIAL cell surfaces, CORPORATE culture, GUT microbiome, BACTERIAL adhesion

Abstract

Microbial community function depends on both taxonomic composition and spatial organization. While composition of the human gut microbiome has been deeply characterized, less is known about the organization of microbes between regions such as lumen and mucosa and the microbial genes regulating this organization. Using a defined 117 strain community for which we generate high-quality genome assemblies, we model mucosa/lumen organization with in vitro cultures incorporating mucin hydrogel carriers as surfaces for bacterial attachment. Metagenomic tracking of carrier cultures reveals increased diversity and strain-specific spatial organization, with distinct strains enriched on carriers versus liquid supernatant, mirroring mucosa/lumen enrichment in vivo. A comprehensive search for microbial genes associated with this spatial organization identifies candidates with known adhesion-related functions, as well as novel links. These findings demonstrate that carrier cultures of defined communities effectively recapitulate fundamental aspects of gut spatial organization, enabling identification of key microbial strains and genes. The organization of gut microbes in lumen and mucosa and the microbial genes regulating this organization remain poorly understood. Here, using in vitro cultures incorporating a complex gut microbial community in mucin-hydrogel carriers, the authors show greater richness and strain-specific spatial organization, enabling discovery of associated genes. [ABSTRACT FROM AUTHOR]

Published

2023

4. Protective effects of peptides on the cell wall structure of yeast under osmotic stress.

Author

Jin, Xiaofan, Chen, Moutong, Coldea, Teodora Emilia, Yang, Huirong, and Zhao, Haifeng

Subjects

*CHITIN, *CELL anatomy, *YEAST, *PEPTIDES, *POLYSACCHARIDES, *CELL analysis

Abstract

Three peptides (LL, LML, and LLL) were used to examine their influences on the osmotic stress tolerance and cell wall properties of brewer's yeast. Results suggested that peptide supplementation improved the osmotic stress tolerance of yeast through enhancing the integrity and stability of the cell wall. Transmission electron micrographs showed that the thickness of yeast cell wall was increased by peptide addition under osmotic stress. Additionally, quantitative analysis of cell wall polysaccharide components in the LL and LLL groups revealed that they had 27.34% and 24.41% higher chitin levels, 25.73% and 22.59% higher mannan levels, and 17.86% and 21.35% higher β-1,3-glucan levels, respectively, than the control. Furthermore, peptide supplementation could positively modulate the cell wall integrity pathway and up-regulate the expressions of cell wall remodeling-related genes, including FKS1, FKS2, KRE6, MNN9, and CRH1. Thus, these results demonstrated that peptides improved the osmotic stress tolerance of yeast via remodeling the yeast cell wall and reinforcing the structure of the cell wall. Key points: • Peptide supplementation improved yeast osmotic stress tolerance via cell wall remodeling. • Peptide supplementation enhanced cell wall thickness and stability under osmotic stress. • Peptide supplementation positively modulated the CWI pathway under osmotic stress. [ABSTRACT FROM AUTHOR]

Published

2022

5. Improved osmotic stress tolerance in brewer's yeast induced by wheat gluten peptides.

Author

Jin, Xiaofan, Yang, Huirong, Chen, Moutong, Coldea, Teodora Emilia, and Zhao, Haifeng

Subjects

*FATTY acid desaturase, *UNSATURATED fatty acids, *GLUTELINS, *YEAST, *PEPTIDES, *GLUTEN, *CELL morphology, *MEMBRANE lipids

Abstract

The influences of three wheat gluten peptides (WGP-LL, WGP-LML, and WGP-LLL) on the osmotic stress tolerance and membrane lipid component in brewer's yeast were investigated. The results demonstrated that the growth and survival of yeast under osmotic stress were enhanced by WGP supplementation. The addition of WGP upregulated the expressions of OLE1 (encoded the delta-9 fatty acid desaturase) and ERG1 (encoded squalene epoxidase) genes under osmotic stress. At the same time, WGP addition enhanced palmitoleic acid (C16:1) content, unsaturated fatty acids/saturated fatty acids ratio, and the amount of ergosterol in yeast cells under osmotic stress. Furthermore, yeast cells in WGP-LL and WGP-LLL groups were more resistant to osmotic stress. WGP-LL and WGP-LLL addition caused 25.08% and 27.02% increase in membrane fluidity, 22.36% and 29.54% reduction in membrane permeability, 18.38% and 14.26% rise in membrane integrity in yeast cells, respectively. In addition, scanning electron microscopy analysis revealed that the addition of WGP was capable of maintaining yeast cell morphology and reducing cell membrane damage under osmotic stress. Thus, alteration of membrane lipid component by WGP was an effective approach for increasing the growth and survival of yeast cells under osmotic stress. Key points: •WGP addition enhanced cell growth and survival of yeast under osmotic stress. •WGP addition increased unsaturated fatty acids and ergosterol contents in yeast. •WGP supplementation improved membrane homeostasis in yeast at osmotic stress. [ABSTRACT FROM AUTHOR]

Published

2022

6. Nonlinear delay differential equations and their application to modeling biological network motifs.

Author

Glass, David S., Jin, Xiaofan, and Riedel-Kruse, Ingmar H.

Subjects

DELAY differential equations, NONLINEAR differential equations, BIOLOGICAL networks, ORDINARY differential equations, BIOLOGICAL models, PHENOMENOLOGICAL biology

Abstract

Biological regulatory systems, such as cell signaling networks, nervous systems and ecological webs, consist of complex dynamical interactions among many components. Network motif models focus on small sub-networks to provide quantitative insight into overall behavior. However, such models often overlook time delays either inherent to biological processes or associated with multi-step interactions. Here we systematically examine explicit-delay versions of the most common network motifs via delay differential equation (DDE) models, both analytically and numerically. We find many broadly applicable results, including parameter reduction versus canonical ordinary differential equation (ODE) models, analytical relations for converting between ODE and DDE models, criteria for when delays may be ignored, a complete phase space for autoregulation, universal behaviors of feedforward loops, a unified Hill-function logic framework, and conditions for oscillations and chaos. We conclude that explicit-delay modeling simplifies the phenomenology of many biological networks and may aid in discovering new functional motifs. Network motif models focus on small sub-networks in biological systems to quantitatively describe overall behavior but they often overlook time delays. Here, the authors systematically examine the most common network motifs via delay differential equations (DDE), often leading to more concise descriptions. [ABSTRACT FROM AUTHOR]

Published

2021