The identification and study of small RNAs, including microRNAs and trans-acting small interfering RNAs, have added a layer of complexity to the many pathways that regulate plant development. These molecules, which function as negative regulators of gene expression, are now known to have greatly expanded roles in a variety of developmental processes affecting all major plant structures, including meristems, leaves, roots, and inflorescences. Mutants with specific developmental phenotypes have also advanced our knowledge of the biogenesis and mode of action of these diverse small RNAs. In addition, previous models on the cell autonomy of microRNAs may have to be revised as more data accumulate supporting their long distance transport. As many of these small RNAs appear to be conserved across different species, knowledge gained from one species is expected to have general application. However, a few surprising differences in small RNA function seem to exist between monocots and dicots regarding meristem initiation and sex determination. Integrating these unique functions into the overall scheme for plant growth will give a more complete picture of how they have evolved as unique developmental systems.