Abstract
The spikelet, which is a short branch bearing the florets, is the fundamental unit of grass inflorescence architecture. In most grasses, spikelets are borne singly on the inflorescence. However, paired spikelets are characteristic of the Andropogoneae, a tribe of 1,000 species including maize (Zea mays). The Suppressor of sessile spikelets1 (Sos1) mutant of maize produces single instead of paired spikelets in the inflorescence. Therefore, the sos1 gene may have been involved in the evolution of paired spikelets. In this article, we show that Sos1 is a semidominant, antimorph mutation. Sos1 mutants have fewer branches and spikelets for two reasons: (1) fewer spikelet pair meristems are produced due to defects in inflorescence meristem size and (2) the spikelet pair meristems that are produced make one instead of two spikelet meristems. The interaction of Sos1 with the ramosa mutants, which produce more branches and spikelets, was investigated. The results show that Sos1 has an epistatic interaction with ramosa1 (ra1), a synergistic interaction with ra2, and an additive interaction with ra3. Moreover, ra1 mRNA levels are reduced in Sos1 mutants, while ra2 and ra3 mRNA levels are unaffected. Based on these genetic and expression studies, we propose that sos1 functions in the ra1 branch of the ramosa pathway controlling meristem determinacy.
Highlights
The spikelet, which is a short branch bearing the florets, is the fundamental unit of grass inflorescence architecture
Because the umc1294 marker was polymorphic between B73 and the original background in which Sos1 arose, this marker was used for genotyping Sos1 in the B73 background
The most striking defect in Sos1 mutants is that the spikelet pair meristems (SPM) initiates one instead of two Spikelet meristems (SM)
Summary
The spikelet, which is a short branch bearing the florets, is the fundamental unit of grass inflorescence architecture. The Suppressor of sessile spikelets (Sos1) mutant of maize produces single instead of paired spikelets in the inflorescence. The interaction of Sos with the ramosa mutants, which produce more branches and spikelets, was investigated. Ra mRNA levels are reduced in Sos mutants, while ra and ra mRNA levels are unaffected Based on these genetic and expression studies, we propose that sos functions in the ra branch of the ramosa pathway controlling meristem determinacy. In maize (Zea mays) inflorescence development, there are multiple types of axillary meristems that differ in their determinacy, resulting in a highly branched inflorescence (Irish, 1997a; Bortiri and Hake, 2007; Barazesh and McSteen, 2008b).
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