The control of carbon allocation, storage and usage is critical for plant growth and development and is exploited for both crop food production and CO 2 capture. Potato tubers are natural carbon reserves in the form of starch that have evolved to allow propagation and survival over winter. They form from stolons, below ground, where they are protected from cold temperatures and animal foraging. We show that BRANCHED1b (BRC1b) acts as a tuberisation repressor in aerial axillary buds, which prevents buds from competing in sink strength with stolons. BRC1b loss of function leads to ectopic production of aerial tubers and reduced underground tuberisation. In buds, BRC1b promotes dormancy, ABA signalling and downregulation of plasmodesmata gene expression. This limits sucrose unloading and access of the tuberigen factor SP6A to axillary buds. Moreover, BRC1b directly interacts with SP6A and blocks its tuber-forming activity in aerial nodes. Altogether these actions help promote tuberisation underground.A central question in plant biology is how carbon partitioning is regulated in response to changing environmental conditions, and how this control is integrated with developmental programs. Plant meristems, groups of undifferentiated, actively dividing cells, are sink organs that use sucrose for respiration, growth and development. Under low sucrose availability, they remain quiescent or dormant. Axillary meristems, shoot meristems located in the leaf axils, can give rise to aerial branches with orthotropic growth that produce leaves, inflorescences and flowers. They can also generate stolons, specialised shoots, homologous to branches, that grow horizontally on the soil surface or below ground and have the potential to generate new clonal plants, thus being strategic for vegetative propagation. Branches and stolons differ in their developmental responses to external stimuli, such as day length (see below).Solanum tuberosum (potato) is one of the best-studied stolon-forming species, as their underground stolons develop energy-rich, starch-accumulating tubers, which constitute a large fraction of the dietary intake for many people worldwide. In the potato landrace ssp. andigena, the stolons become strong sinks when winter approaches, and form tubers at their sub-apical region. Tubers overwinter buried in soil, where they are protected from cold and animal foraging, to generate entirely new plants in spring.Tuberisation is controlled by the FLOWERING LOCUS T (FT)-like SELF-PRUNING 6A (SP6A) gene. In potato ssp. andigena, activation of this gene is fully dependent on short days (SD). In long days (LD), the CONSTANS-like1 (COL1) transcription factor represses SP6A expression through the activation of another FT-like gene, SP5G 1,2 . In SD, lack of SP5G allows SP6A activation, and the SP6A protein is then phloem-transported from leaves to stolons. At the stolon apices, SP6A form a Tuberigen Activation Complex (TAC) that acts to promote tuber formation 3,4 .Unlike stolons, neither branches nor branch primordia, namely axillar...
