The raison d'etre of the germline is to produce oocytes and sperm that pass genetic material and cytoplasmic constituents to the next generation. To achieve this goal, many developmental processes must be executed and coordinated. ERK, the terminal MAP kinase of a number of signaling pathways, controls many aspects of development. Here we present a comprehensive analysis of MPK-1 ERK in Caenorhabditis elegans germline development. MPK-1 functions in four developmental switches: progression through pachytene, oocyte meiotic maturation/ovulation, male germ cell fate specification, and a nonessential function of promoting the proliferative fate. MPK-1 also regulates multiple aspects of cell biology during oogenesis, including membrane organization and morphogenesis: organization of pachytene cells on the surface of the gonadal tube, oocyte organization and differentiation, oocyte growth control, and oocyte nuclear migration. MPK-1 activation is temporally/spatially dynamic and most processes appear to be controlled through sustained activation. MPK-1 thus may act not only in the control of individual processes but also in the coordination of contemporaneous processes and the integration of sequential processes. Knowledge of the dynamic activation and diverse functions of MPK-1 provides the foundation for identification of upstream signaling cascades responsible for region-specific activation and the downstream substrates that mediate the various processes. I N the generation of oocytes and sperm, perhaps the most complex cells in animals, the germline lineage undergoes a multifaceted developmental process that begins in embryogenesis and continues into adulthood. While the details of the steps can differ between species due to differences in reproductive biology, a core set of events occurs in animals: germ cell fate specification, incorporation into the gonad, sexual fate specification, proliferative expansion, and gamete production. Two interconnected differentiation programs define gamete production: (1) meiosis where chromosomes pair, recombine, and then segregate to give a reassorted haploid content and (2) gametogenesis where biosynthetic and morphogenetic processes generate the large nutrient and developmental information-rich oocyte and the small motile sperm. In aggregate, these processes are essential to pass genetic material from generation to generation and to form the totipotent zygote necessary for the development of a new individual. Disruption of germline development can lead to sterility, germline tumors, and birth defects. Thus an important goal is to define the pathways and gene products that control and execute the various steps of germline development.The MAP kinase extracellular signal-regulated kinase (ERK) functions in many aspects of animal development and homeostasis (Marshall 1995;Rubin et al. 1997;Schlessinger 2000;Sundaram 2006). ERK is the terminal regulator of signaling cascades such as canonical receptor tyrosine kinase signaling, which contains core members, including the RA...