Leveraging Super High Optical Resolution Microscopy to Probe the Interaction Zone Between Clostridium thermocellum and Biomass

John Yarbrough; Dominik Stich; Daehwan Chung; Neal Hengge; Todd Vinzant; Stu Huang; Yining Zeng; Bryon Donohoe; Michael Himmel; Yannick Bomble; Gerald Tuskan

Leveraging Super High Optical Resolution Microscopy to Probe the Interaction Zone Between Clostridium thermocellum and Biomass

John Yarbrough, Dominik Stich, Daehwan Chung, Neal Hengge, Todd Vinzant, Stu Huang, Yining Zeng, Bryon Donohoe, Michael Himmel, Yannick Bomble, Gerald Tuskan

Biosciences Center

Research output: NREL › Poster

Abstract

This poster, part of the Pacific Northwest National Laboratory-sponsored Integration 2020: Visualizing the Proteome virtual conference, discusses super high optical resolution microscopy to probe the interaction zone between Clostritium thermocellum and biomass. Clostridium thermocellum is one of the most efficient microorganisms for the deconstruction of biomass. To achieve this high level of cellulolytic activity, C. thermocellum uses large multienzyme complexes known as cellulosomes to sugars in 4-5 break down polysaccharides found in plant cell walls. The attachment of bacterial switchgrass 70% cells to the nearby substrate via the cellulosome has been hypothesized to be the reason for this high efficiency. The region lying between the cell and the substrate has shown great variation and dynamics that are affected by the growth stage of cells and the substrate used for growth.

Original language	American English
State	Published - 2020

Publication series

Name	Presented at the Integration 2020: Visualizing the Proteome, 5-8 October 2020

NREL Publication Number

NREL/PO-2700-78163

Keywords

bacteria
biomass
cellulosome
Clostridium thermocellum
microscopy
super-high resolution

Access to Document

https://www.nrel.gov/docs/fy22osti/78163.pdf

Cite this

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title = "Leveraging Super High Optical Resolution Microscopy to Probe the Interaction Zone Between Clostridium thermocellum and Biomass",

abstract = "This poster, part of the Pacific Northwest National Laboratory-sponsored Integration 2020: Visualizing the Proteome virtual conference, discusses super high optical resolution microscopy to probe the interaction zone between Clostritium thermocellum and biomass. Clostridium thermocellum is one of the most efficient microorganisms for the deconstruction of biomass. To achieve this high level of cellulolytic activity, C. thermocellum uses large multienzyme complexes known as cellulosomes to sugars in 4-5 break down polysaccharides found in plant cell walls. The attachment of bacterial switchgrass 70% cells to the nearby substrate via the cellulosome has been hypothesized to be the reason for this high efficiency. The region lying between the cell and the substrate has shown great variation and dynamics that are affected by the growth stage of cells and the substrate used for growth.",

keywords = "bacteria, biomass, cellulosome, Clostridium thermocellum, microscopy, super-high resolution",

author = "John Yarbrough and Dominik Stich and Daehwan Chung and Neal Hengge and Todd Vinzant and Stu Huang and Yining Zeng and Bryon Donohoe and Michael Himmel and Yannick Bomble and Gerald Tuskan",

year = "2020",

language = "American English",

series = "Presented at the Integration 2020: Visualizing the Proteome, 5-8 October 2020",

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T1 - Leveraging Super High Optical Resolution Microscopy to Probe the Interaction Zone Between Clostridium thermocellum and Biomass

AU - Yarbrough, John

AU - Stich, Dominik

AU - Chung, Daehwan

AU - Hengge, Neal

AU - Vinzant, Todd

AU - Huang, Stu

AU - Zeng, Yining

AU - Donohoe, Bryon

AU - Himmel, Michael

AU - Bomble, Yannick

AU - Tuskan, Gerald

PY - 2020

Y1 - 2020

N2 - This poster, part of the Pacific Northwest National Laboratory-sponsored Integration 2020: Visualizing the Proteome virtual conference, discusses super high optical resolution microscopy to probe the interaction zone between Clostritium thermocellum and biomass. Clostridium thermocellum is one of the most efficient microorganisms for the deconstruction of biomass. To achieve this high level of cellulolytic activity, C. thermocellum uses large multienzyme complexes known as cellulosomes to sugars in 4-5 break down polysaccharides found in plant cell walls. The attachment of bacterial switchgrass 70% cells to the nearby substrate via the cellulosome has been hypothesized to be the reason for this high efficiency. The region lying between the cell and the substrate has shown great variation and dynamics that are affected by the growth stage of cells and the substrate used for growth.

AB - This poster, part of the Pacific Northwest National Laboratory-sponsored Integration 2020: Visualizing the Proteome virtual conference, discusses super high optical resolution microscopy to probe the interaction zone between Clostritium thermocellum and biomass. Clostridium thermocellum is one of the most efficient microorganisms for the deconstruction of biomass. To achieve this high level of cellulolytic activity, C. thermocellum uses large multienzyme complexes known as cellulosomes to sugars in 4-5 break down polysaccharides found in plant cell walls. The attachment of bacterial switchgrass 70% cells to the nearby substrate via the cellulosome has been hypothesized to be the reason for this high efficiency. The region lying between the cell and the substrate has shown great variation and dynamics that are affected by the growth stage of cells and the substrate used for growth.

KW - bacteria

KW - biomass

KW - cellulosome

KW - Clostridium thermocellum

KW - microscopy

KW - super-high resolution

M3 - Poster

T3 - Presented at the Integration 2020: Visualizing the Proteome, 5-8 October 2020

ER -

Leveraging Super High Optical Resolution Microscopy to Probe the Interaction Zone Between Clostridium thermocellum and Biomass

Abstract

Publication series

NREL Publication Number

Keywords

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