Molecular knowledge of pathways regulating seed formation in legumes, remains scarce. Thirteen isolated cell-type transcriptomes were developed, spanning temporal events of male and female gametogenesis and seed initiation, to examine pathways involved in cowpea seed formation. In situ hybridization confirmed localization of in silico identified cell-specific genes, verifying transcriptome utility. Cowpea and Arabidopsis reproductive cells showed some conservation in regulators enabling cell-type expression as some cowpea cell-specific genes promoters and their Arabidopsis homologs directed expression to identical reproductive cell-types in transgenic plants. In silico analyses revealed gene expression similarities and differences with genes in pathways regulating reproductive events in other plants. Meiosis-related genes were expressed at mitotic stages of gametogenesis and during sporophytic development in cowpea. Plant hormone pathways showing preferential expression at particular reproductive stages were identified. Expression of epigenetic pathways, resembling those found in Arabidopsis, including microRNA mediated gene silencing, RNA directed DNA methylation and histone modification were associated with particular stages of male and female gametophyte development, suggesting roles in gametogenic cell specification and elaboration. Analyses of cell-cycle related gene expression in mature cowpea female gametophytes, indicated that the egg and central cell were arrested at the G1/S and G2/M cell cycle phases, respectively, prior to fertilization. Pre-fertilization female gametophyte arrest was characterized by barely detectable auxin biosynthesis gene expression levels, and elevated expression of genes involved in RNA-mediated gene silencing and histone modification. These transcriptomes provide a useful resource for additional interrogation to support functional analyses for development of higher yielding cowpea and syntenic legume crops. One sentence summary Transcriptomes from cowpea reproductive cell-types isolated in temporal sequence from meiosis to seed initiation revealed cell-type gene expression profiles enabling comparison with gene expression pathways known to function in cell specification and reproductive development in other plants.