StInvInh2 as an inhibitor of StvacINV1 regulates the cold-induced sweetening of potato tubers by specifically capping vacuolar invertase activity.

Reducing sugar (RS) accumulation in cold-stored potato tubers, known as cold-induced sweetening (CIS), is a crucial factor causing unacceptable colour changes and acrylamide formation of fried products. The activity of vacuolar invertase (StvacINV1) is proved important for the CIS process, and invertase inhibitors are speculated to play roles in the post-translational regulation of StvacINV1 activity. In our previous research, two putative inhibitors (StInvInh2A and StInvInh2B) of StvacINV1 were implied to be involved in potato CIS. Here, we further reported that StInvInh2A and StInvInh2B had similar function that specifically inhibited StvacINV1 activity in potatoes. The genetic transformation of these inhibitor genes in potatoes by overexpression in CIS-sensitive and RNAi-silenced in CIS-resistant genotypes showed that StvacINV1 activity was strongly regulated by alteration of the transcripts of the inhibitors without impacting on the expression of StvacINV1. A negative power relationship was found between the transcripts of the inhibitors and StvacINV1 activity, suggesting 1) a transcriptional determination of the inhibitory capacity of StInvInh2A and StInvInh2B and 2) a significant inhibitory role of these inhibitors in post-translational modulation of StvacINV1. The results also demonstrated that depression of StvacINV1 activity through overexpression of StInvInh2A and StInvInh2B weakened accumulation of RS and acrylamide in cold-stored tubers and consequently improved the chip quality. The present research strongly suggest that both StInvInh2A and StInvInh2B function as inhibitors of StvacINV1 and play similar roles in regulating potato CIS by capping StvacINV1 activity. These inhibitors could be novel genetic resources applicable for improving quality of potato processing products.