Deceleration and acceleration in the rate of posterior neuropore closure during neurulation in the curly tail (ct) mouse embryo

Summary Curly tail (ct) is a mouse mutant producing spinal neural tube defects as a result of delayed closure of the posterior neuropore (PNP). The purpose of the present study was to determine in ct/ct embryos the time of onset of the delay in PNP closure, and the pattern of this closure, as well as to study the possibility that reopening of the neural tube occurs. Normal spinal neurulation was studied in non-mutant Swiss (Sw) embryos. In the latter, the average PNP length diminished steadily between the 7- and 25-somite stages, and then decreased more rapidly, indicating an acceleration of closure rate, until the 30- to 32-somite stage, when all PNPs closed. PNP width decreased steadily between the stages of 7 and 30 somites. In ct/ct embryos the average PNP length showed a slight increase between the stage of 23 to 28 somites, indicating a temporary deceleration of closure rate, and the range of PNP sizes increased markedly. This was followed by a decrease in PNP length until the 37-somite stage, indicating an acceleration of closure rate. From the stage of 32 somites onwards, the proportion of embryos with closed PNPs gradually increased to 90%. The population of ct/ct embryos was subdivided. Embryos with large PNPs showed a marked deceleration of closure rate during a period of 11 somite stages, followed by a brief but very high acceleration of closure rate. This resulted in closure of the PNP in a proportion of these embryos, while in the remainder of the embryos the deceleration phase had been too enhanced to allow complete catch up of closure during the acceleration phase; these embryos would develop spina bifida. Embryos with relative small PNPs also showed a deceleration of closure rate, but only during a period of four somite stages. This was followed by an acceleration, resulting in closure of all PNPs at the stage of 32 to 33 somites. The enlargement of the PNP in ct/ct embryos was not due to re-opening of a closed neural tube, but resulted from a sharp decline in the rate of PNP closure combined with a normal rate of caudal elongation of the embryo. It is concluded that the ct strain forms a homogeneous population, with a large variation of its specific phenotype: deceleration of PNP closure during a restricted period. The disturbance of spinal neurulation in ct/ct embryos takes the form of a deceleration/acceleration pattern, resulting in a net delay of closure. It is suggested that, due to the ct mutation, forces are generated in the embryonic axis which oppose a normal neurulation process at a specific stage of development.