Abstract
BackgroundPlant-based milk alternatives are more popular than ever, and chickpea-based milks are among the most commercially relevant products. Unfortunately, limited nutritional value because of low levels of the essential amino acid l-lysine, low digestibility and unpleasant taste are challenges that must be addressed to improve product quality and meet consumer expectations.ResultsUsing in-silico screening and food safety classifications, 31 strains were selected as potential l-lysine producers from approximately 2,500 potential candidates. Beneficially, 30% of the isolates significantly accumulated amino acids (up to 1.4 mM) during chickpea milk fermentation, increasing the natural level by up to 43%. The best-performing strains, B. amyloliquefaciens NCC 156 and L. paracasei subsp. paracasei NCC 2511, were tested further. De novo lysine biosynthesis was demonstrated in both strains by 13C metabolic pathway analysis. Spiking small amounts of citrate into the fermentation significantly activated l-lysine biosynthesis in NCC 156 and stimulated growth. Both microbes revealed additional benefits in eliminating indigestible sugars such as stachyose and raffinose and converting off-flavour aldehydes into the corresponding alcohols and acids with fruity and sweet notes.ConclusionsB. amyloliquefaciens NCC 156 and L. paracasei subsp. paracasei NCC 2511 emerged as multi-benefit microbes for chickpea milk fermentation with strong potential for industrial processing of the plant material. Given the high number of l-lysine-producing isolates identified in silico, this concept appears promising to support strain selection for food fermentation.
Highlights
Plant-based milk alternatives are more popular than ever, and chickpea-based milks are among the most commercially relevant products
Genome‐based selection of food‐grade microbes for l‐lysine production Bacterial genomes of the Nestlé Culture Collection (NCC) were analysed for their features related to l-lysine, including l-lysine biosynthesis, l-lysine degradation, and pathways competing with l-lysine biosynthesis for carbon precursors (Fig. 1)
Each of the microbes exhibited multiple benefits: an improved l-lysine content due to de novo synthesis of the amino acid, which was proven in 13C experiments; an improved digestibility due to the removal of raffinose and stachyose; and an improved flavour profile due the elimination of off-flavour aldehydes and the generation of sweet and fruity aromas
Summary
Plant-based milk alternatives are more popular than ever, and chickpea-based milks are among the most commercially relevant products. Suspensions of chickpea flour (termed chickpea milk below due to their milk-like appearance) do not match animal milk in all desired characteristics, which is a limitation that is generally observed for plantbased milk alternatives [7] This limitation holds for the essential amino acid l-lysine, which is required for hormone formation, catalytic and structural proteins, and immune system support and is one of the most impacting nutrients [8]. Chickpea milk contains elevated levels of indigestible sugars such as raffinose and stachyose, which cause flatulence, diarrhoea, and other discomfort upon consumption [11] It exhibits a grassy and beany taste that does not meet consumer expectations [12]
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