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Development of a high-throughput growth assay for bacteria or yeasts using an agar-based insoluble carbon source immobilization method

Liang, Jiabao ; Naimi, Isabella S. ; Narayanan, Achala ; Maillard, François LU ; Kennedy, Peter G. and Gardner, Jeffrey G. (2026) In Microbiology spectrum 14(6). p.1-14
Abstract

Polysaccharide degradation by microorganisms is essential in driving global nutrient cycling, developing renewable fuels or chemicals, and promoting human gut health. However, complex polysaccharides are often insoluble, making it challenging to study degradation with soluble enzymes or to measure microbial growth. Several protocols exist to address this challenge, including 3D-printed biomass containment devices or agar capture systems to facilitate the study of insoluble carbohydrate degradation. While these methods are functional, they are constrained by variable substrate loading and time-consuming preparation. To address these shortcomings, a 3D-printed pipette was designed and tested as part of a newly developed agar... (More)

Polysaccharide degradation by microorganisms is essential in driving global nutrient cycling, developing renewable fuels or chemicals, and promoting human gut health. However, complex polysaccharides are often insoluble, making it challenging to study degradation with soluble enzymes or to measure microbial growth. Several protocols exist to address this challenge, including 3D-printed biomass containment devices or agar capture systems to facilitate the study of insoluble carbohydrate degradation. While these methods are functional, they are constrained by variable substrate loading and time-consuming preparation. To address these shortcomings, a 3D-printed pipette was designed and tested as part of a newly developed agar immobilization method to quantitatively monitor the degradation of insoluble polysaccharides for a 96-well microtiter assay. The pipette and method were validated via two mechanisms. First, growth analyses of Cellvibrio japonicus wild-type or bgl2A, cbp2D, and cbp2E single deletion mutant strains were conducted using glucose, barley β-glucan, starch, cellulose, chitin, pectin, galactan, or intact yeast biomass as a sole carbon source to benchmark the new method against previously described methods. Second, the agar pipette was used to screen the growth of bacteria or yeasts capable of utilizing insoluble polysaccharides as the sole carbon source. The 3D-printed pipette and agar immobilization method enabled a faster, more consistent, and cost-effective way for high-throughput screening of bacterial or yeast growth using insoluble carbohydrates, suggesting that it can be a useful tool for environmental and applied microbial research. IMPORTANCE The insolubility of many polysaccharides contributes to the challenge of studying how these substrates are deconstructed by diverse microorganisms, which limits our understanding of environmental processes dependent on microbes and slows progress in the development of biotechnologies based on insoluble polysaccharide degradation (i.e., renewable fuels and chemicals). Previous methods to circumvent this challenge are typically time-consuming, resource-intensive, and not compatible with all types of insoluble polysaccharides. Therefore, we designed a 3D-printed pipette as part of an agar immobilization method to enable 96-well microplate microbial growth and enzyme assays using insoluble substrates. Validation of this microtiter assay indicated reduced preparation time and material required for high-throughput screening compared to currently used protocols. Furthermore, the method identified new growth phenotypes for a model saprophytic bacterium and accurately tracked growth patterns from a collection of environmentally derived bacteria and yeasts. These results demonstrate the versatility of the 3D pipette and associated method.

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author
; ; ; ; and
organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
3D printing, carbohydrate, Cellvibrio japonicus, chitin, glycan, pectin, polysaccharide
in
Microbiology spectrum
volume
14
issue
6
pages
14 pages
publisher
American Society for Microbiology
external identifiers
  • pmid:42059392
  • scopus:105041221047
ISSN
2165-0497
DOI
10.1128/spectrum.04171-25
language
English
LU publication?
yes
id
2fd6d46b-f737-4dcb-954c-33c210c65cc3
date added to LUP
2026-07-03 14:45:35
date last changed
2026-07-03 14:46:50
@article{2fd6d46b-f737-4dcb-954c-33c210c65cc3,
  abstract     = {{<p>Polysaccharide degradation by microorganisms is essential in driving global nutrient cycling, developing renewable fuels or chemicals, and promoting human gut health. However, complex polysaccharides are often insoluble, making it challenging to study degradation with soluble enzymes or to measure microbial growth. Several protocols exist to address this challenge, including 3D-printed biomass containment devices or agar capture systems to facilitate the study of insoluble carbohydrate degradation. While these methods are functional, they are constrained by variable substrate loading and time-consuming preparation. To address these shortcomings, a 3D-printed pipette was designed and tested as part of a newly developed agar immobilization method to quantitatively monitor the degradation of insoluble polysaccharides for a 96-well microtiter assay. The pipette and method were validated via two mechanisms. First, growth analyses of Cellvibrio japonicus wild-type or bgl2A, cbp2D, and cbp2E single deletion mutant strains were conducted using glucose, barley β-glucan, starch, cellulose, chitin, pectin, galactan, or intact yeast biomass as a sole carbon source to benchmark the new method against previously described methods. Second, the agar pipette was used to screen the growth of bacteria or yeasts capable of utilizing insoluble polysaccharides as the sole carbon source. The 3D-printed pipette and agar immobilization method enabled a faster, more consistent, and cost-effective way for high-throughput screening of bacterial or yeast growth using insoluble carbohydrates, suggesting that it can be a useful tool for environmental and applied microbial research. IMPORTANCE The insolubility of many polysaccharides contributes to the challenge of studying how these substrates are deconstructed by diverse microorganisms, which limits our understanding of environmental processes dependent on microbes and slows progress in the development of biotechnologies based on insoluble polysaccharide degradation (i.e., renewable fuels and chemicals). Previous methods to circumvent this challenge are typically time-consuming, resource-intensive, and not compatible with all types of insoluble polysaccharides. Therefore, we designed a 3D-printed pipette as part of an agar immobilization method to enable 96-well microplate microbial growth and enzyme assays using insoluble substrates. Validation of this microtiter assay indicated reduced preparation time and material required for high-throughput screening compared to currently used protocols. Furthermore, the method identified new growth phenotypes for a model saprophytic bacterium and accurately tracked growth patterns from a collection of environmentally derived bacteria and yeasts. These results demonstrate the versatility of the 3D pipette and associated method.</p>}},
  author       = {{Liang, Jiabao and Naimi, Isabella S. and Narayanan, Achala and Maillard, François and Kennedy, Peter G. and Gardner, Jeffrey G.}},
  issn         = {{2165-0497}},
  keywords     = {{3D printing; carbohydrate; Cellvibrio japonicus; chitin; glycan; pectin; polysaccharide}},
  language     = {{eng}},
  number       = {{6}},
  pages        = {{1--14}},
  publisher    = {{American Society for Microbiology}},
  series       = {{Microbiology spectrum}},
  title        = {{Development of a high-throughput growth assay for bacteria or yeasts using an agar-based insoluble carbon source immobilization method}},
  url          = {{http://dx.doi.org/10.1128/spectrum.04171-25}},
  doi          = {{10.1128/spectrum.04171-25}},
  volume       = {{14}},
  year         = {{2026}},
}