# Spore immobilized enzymes for the multi-step synthesis of cellobiose

**Authors:** Jan Benedict Spannenkrebs, Leesa Jane Klau, Marianna Karava, Finn Lillelund Aachmann, Johannes Kabisch

PMC · DOI: 10.1186/s12934-026-02943-w · 2026-02-03

## TL;DR

This paper presents a method to immobilize enzymes on bacterial spores for the efficient, multi-step synthesis of cellobiose, a valuable disaccharide.

## Contribution

The first use of multiple enzymes displayed on spore surfaces during a reaction cascade for cellobiose synthesis.

## Key findings

- Spore-immobilized enzymes maintained significant activity over multiple reaction cycles.
- A one-pot reaction achieved 90% yield of cellobiose and retained activity after five cycles.
- Adding calcium improved two-pot reaction yield from 60% to 80% by removing excess phosphate.

## Abstract

Cellobiose (4-O-β-D-Glucopyranosyl-D-glucopyranose) is an important disaccharide utilized, for example in food and cosmetics. It can be enzymatically synthesized involving two steps from sucrose and glucose, where first the sucrose undergoes phosphorolysis by sucrose phosphorylase, yielding glucose 1-phosphate and fructose. Glucose 1-phosphate is then combined with glucose into cellobiose, releasing phosphate in a reaction catalyzed by cellobiose phosphorylase. To better control and reuse the enzymes in the two main reaction steps, immobilization on Bacillus subtilis spores is a promising approach due to the ease of production and recyclability.

Here we describe the display of a sucrose phosphorylase and a cellobiose phosphorylase on B. subtilis spores through fusion with the crust protein CotY, to our knowledge marking the first use of multiple enzymes directly displayed on the spore surface during sporulation in a reaction cascade. While immobilization had no effect on thermostability, we demonstrate the recyclability of the individual spore variants over four reaction cycles at 45 °C with sucrose phosphorylase maintaining 35% of its initial activity and cellobiose phosphorylase maintaining 65%. Both spore variants were used together to catalyse a reaction cascade in a separated two-pot, as well as in a one-pot reaction. The one-pot reaction achieved a 90% yield with respect to the initially available 40 mM of glucose. The one-pot cascade maintained activity after being recycled five times over the course of 120 hours. Furthermore, we report on improving the reaction yield in the two-pot reaction from 60% to 80% by using calcium to precipitate excess phosphate.

In this study we demonstrate that spores are a suitable immobilization platform for multistage reaction cascades. The spores displaying biocatalysts can be recovered and reused over multiple reaction cycles. The immobilization of glycosylic enzymes on spores enables cost-effective, scalable enzyme production on a temperature-resistant carrier that facilitates purification. The potential modularity of this approach adds to the adaptability of the system to different requirements in terms of substrate and product.

The online version contains supplementary material available at 10.1186/s12934-026-02943-w.

## Linked entities

- **Proteins:** cotY (outer spore coat protein (crust layer, insoluble fraction))
- **Chemicals:** cellobiose (PubChem CID 439178), sucrose (PubChem CID 5988), glucose (PubChem CID 5793), glucose 1-phosphate (PubChem CID 65533), fructose (PubChem CID 5984), phosphate (PubChem CID 1061), calcium (PubChem CID 5460341)
- **Species:** Bacillus subtilis (taxon 1423)

## Full-text entities

- **Chemicals:** cellobiose (MESH:D002475)

## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12903485/full.md

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Source: https://tomesphere.com/paper/PMC12903485