Taylor M. Nichols scite author profile

Bacterial microcompartments (MCPs) are protein-based organelles that encapsulate metabolic pathways. Metabolic engineers have recently sought to repurpose MCPs to encapsulate heterologous pathways to increase flux through pathways of interest. As MCP engineering becomes more common, standardized methods for analyzing changes to MCPs and interpreting results across studies will become increasingly important. In this study, we demonstrate that different imaging techniques yield variations in the apparent size of purified MCPs from Salmonella enterica serovar Typhimurium LT2, likely due to variations in sample preparation methods. We provide guidelines for preparing samples for MCP imaging and outline expected variations in apparent size and morphology between methods. With this report we aim to establish an aid for comparing results across studies.

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Cargo encapsulation in bacterial microcompartments: Methods and analysis

Nichols

Kennedy

Tullman‐Ercek

2019

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Metabolic engineers seek to produce high-value products from inexpensive starting materials in a sustainable and cost-effective manner by using microbes as cellular factories. However, pathway development and optimization can be arduous tasks, complicated by pathway bottlenecks and toxicity. Pathway organization has emerged as a potential solution to these issues, and the use of protein- or DNA-based scaffolds has successfully increased the production of several industrially relevant compounds. These efforts demonstrate the usefulness of pathway colocalization and spatial organization for metabolic engineering applications. In particular, scaffolding within an enclosed, subcellular compartment shows great promise for pathway optimization, offering benefits such as increased local enzyme and substrate concentrations, sequestration of toxic or volatile intermediates, and alleviation of cofactor and resource competition with the host. Here, we describe the 1,2-propanediol utilization (Pdu) bacterial microcompartment (MCP) as an enclosed scaffold for pathway sequestration and organization. We first describe methods for controlling Pdu MCP formation, expressing and encapsulating heterologous cargo, and tuning cargo loading levels. We further describe assays for analyzing Pdu MCPs and assessing encapsulation levels. These methods will enable the repurposing of MCPs as tunable nanobioreactors for heterologous pathway encapsulation.

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A genomic integration platform for heterologous cargo encapsulation in 1,2-propanediol utilization bacterial microcompartments

Nichols

Kennedy

Tullman‐Ercek

2020

Biochemical Engineering Journal

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Bacterial microcompartments: tiny organelles with big potential

Kennedy

Mills

Nichols

et al. 2021

Current Opinion in Microbiology

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Control of upper gastrointestinal bleeding with a microcrystalline collagen hemostat

et al. 1982

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A microcrystalline collagen hemostat (MCH) widely used in general surgery was tested in the control of bleeding from experimentally produced gastric ulcers. Five dogs had a gastrotomy and were given heparin. Using the standard "ulcer maker," three sets of three ulcers were made in the gastric mucosa of each animal. Blood from each ulcer was collected for a 5-min period to allow for stabilization of bleeding. MCH powder or slurry or no MCH was placed directly on one ulcer of each set in random order. The bleeding rate for the next 10 min was measured. Mean decrements in the bleeding rate for slurry MCH and dry MCH-treated ulcers were 87% and 81%, respectively, compared with 51% for controls, P less than 0.05. Twelve MCH-treated ulcers, but no control ulcer, stopped bleeding completely, P less than 0.01. Preliminary observations show that MCH slurry can be applied through an endoscope and may be hemostatically effective in man. MCH may have a role in the endoscopic control of gastrointestinal bleeding.

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Taylor M. Nichols

Apparent size and morphology of bacterial microcompartments varies with technique

Cargo encapsulation in bacterial microcompartments: Methods and analysis

A genomic integration platform for heterologous cargo encapsulation in 1,2-propanediol utilization bacterial microcompartments

Bacterial microcompartments: tiny organelles with big potential

Control of upper gastrointestinal bleeding with a microcrystalline collagen hemostat

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