Abstract
We describe a novel spontaneous mouse mutant, laggard (lag), characterized by a flat head, motor impairment and growth retardation. The mutation is inherited as an autosomal recessive trait, and lag/lag mice suffer from cerebellar ataxia and die before weaning. lag/lag mice exhibit a dramatic reduction in brain size and slender optic nerves. By positional cloning, we identify a splice site mutation in Kif14. Transgenic complementation with wild-type Kif14-cDNA alleviates ataxic phenotype in lag/lag mice. To further confirm that the causative gene is Kif14, we generate Kif14 knockout mice and find that all of the phenotypes of Kif14 knockout mice are similar to those of lag/lag mice. The main morphological abnormality of lag/lag mouse is severe hypomyelination in central nervous system. The lag/lag mice express an array of myelin-related genes at significantly reduced levels. The disrupted cytoarchitecture of the cerebellar and cerebral cortices appears to result from apoptotic cell death. Thus, we conclude that Kif14 is essential for the generation and maturation of late-developing structures such as the myelin sheath, cerebellar and cerebral cortices. So far, no Kif14-deficient mice or mutation in Kif14 has ever been reported and we firstly define the biological function of Kif14 in vivo. The discovery of mammalian models, laggard, has opened up horizons for researchers to add more knowledge regarding the etiology and pathology of brain malformation.
Highlights
Mammalian brain development depends on a complex and highly regulated sequence of events, and can be divided into four overlapping processes: cell birth, migration, formation of connections and myelination
By postnatal day 10 (P10), the mutants exhibited an overt ataxic phenotype that increased in severity over time
At P12, lag/lag mice were unable to stand for 10 s on a narrow (5-cmwide) platform, whereas normal littermates maintained their balance for 1 min (Figure 1B)
Summary
Mammalian brain development depends on a complex and highly regulated sequence of events, and can be divided into four overlapping processes: cell birth (neurogenesis), migration, formation of connections (including elaboration of processes, synapse formation, cell death and axonal regression) and myelination. Genetic mutations that affect the ability of neural cells to undergo these orderly and precisely paced developmental steps result in developmental arrest, often leading to death of the affected cell populations. Genetic mapping of such mutations in mice has led to the identification of proteins essential for neuronal migration, differentiation and survival. These mouse neurological mutants exhibit defects in a variety of processes, and include open brain (affecting neural tube development) [1,2], staggerer and lurcher (causing degeneration of Purkinje cells and granule cells) [3], weaver and reeler (affecting neuronal migration) [4,5,6], and jimpy and quaking (affecting myelination) [7]. Several factors regulate the differentiation of OPCs into mature oligodendrocytes, little is known about the effectors that control the conversion of pre-myelinating oligodendrocytes into myelinating oligodendrocytes
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