For over a century, the pursuit of a sugar substitute offering the same delightful taste without the associated health concerns has captivated scientists and food innovators. From the introduction of saccharin in the 19th century to contemporary options like stevia and monk fruit, the core objective remains consistent. The real challenge lies in replicating sugar’s enjoyable flavor profile while mitigating risks like weight gain, dental issues, and the potential for insulin resistance and type 2 diabetes.
Excitingly, recent research published in Cell Reports physical Science indicates we may be closer than ever to achieving this goal. Researchers at Tufts University have pioneered a novel biosynthetic process for producing tagatose, a naturally occurring yet exceptionally rare sugar. This innovative sugar closely mirrors the taste of traditional table sugar and presents a promising avenue for enjoying sweetness with potentially fewer adverse health effects, and even some added advantages.
What Exactly is Tagatose?
Tagatose exists naturally, but in significantly smaller amounts compared to commonly consumed sugars like glucose, fructose, and sucrose. It’s found in dairy products, forming when lactose breaks down through heat or enzymatic processes during the creation of foods like yogurt, cheese, and kefir.
Trace amounts of tagatose are also present in fruits such as apples,pineapples,and oranges,typically constituting less than 0.2% of their total sugar content. Due to this limited natural availability, tagatose is generally manufactured rather than extracted directly from food sources.
The Science Behind Bacterial Engineering
“Existing methods for tagatose production are frequently enough inefficient and costly,” explains a leading researcher in the field.
To overcome these limitations, the research team devised a new production strategy utilizing genetically engineered bacteria. “We engineered Escherichia coli bacteria to function as miniature factories, equipped with the necessary enzymes to convert readily available glucose into tagatose.This approach is considerably more economically viable than our previous methods, which relied on the more scarce and expensive galactose.”
The bacteria where genetically modified to include a newly discovered enzyme from slime mold, known as galactose-1-phosphate-selective phosphatase (Gal1P). This enzyme facilitates the conversion of glucose into galactose. Afterward, another bacterial enzyme, arabinose isomerase, transforms the galactose into tagatose.
This innovative method allows the engineered bacteria to convert glucose into tagatose with impressive yields, reaching up to 95%. This represents a substantial improvement over conventional manufacturing techniques, which typically yield between 40% and 77%. The increased efficiency also translates to notable cost savings.