Human midsized neurofilament subunit induces motor neuron disease in transgenic mice.

Aberrant accumulation of neurofilaments is a feature of human motor neuron diseases. Experimentally motor neuron disease can be induced in transgenic mice by overexpressing the mouse neurofilament light subunit (NF-L), the human heavy subunit (NF-H), or mouse peripherin. Here we describe that mice harboring a bacterial artificial chromosome (BAC) transgene containing the human midsized neurofilament subunit (NF-M) gene develop a progressive hind limb paralysis associated with neurofilamentous accumulations in ventral horn motor neurons and axonal loss in ventral motor roots. Biochemical studies revealed that all three mouse neurofilament subunits along with the human NF-M contributed to filament formation, although filaments contained less peripherin. In addition the endogenous mouse NF-M became less phosphorylated in the presence of the human protein and accumulated in the cell bodies of affected neurons even though phosphorylated human NF-M did not. Remaining motor axons contained an increased density of neurofilaments and morphometric studies showed that principally small myelinated axons were lost in the transgenic animals. Removing half of the mouse NF-M by breeding the transgene onto the mouse NF-M heterozygous null background offered no protection against the development of disease, arguing that the effect is not simply due to elevation of total NF-M. Collectively these studies argue that the human and mouse NF-M proteins exhibit distinct biochemical properties and within mouse neurons are not interchangeable and that indeed the human protein may be toxic to some mouse neurons. These studies have implications for the use of human neurofilament transgenic mice as models of amyotrophic lateral sclerosis.

Ectopic expression of Gcm1 induces congenital spinal cord abnormalities.

Brief ectopic expression of Gcm1 in mouse embryonic tail bud profoundly affects the development of the nervous system. All mice from 5 independently derived transgenic lines exhibited either one or both of two types of congenital spinal cord pathologies: failure of the neural tube to close (spina bifida) and multiple neural tubes (diastematomyelia). Because the transgene is expressed only in a restricted caudal region and only for a brief interval (E8.5 to E13.5), there was no evidence of embryonic lethality. The dysraphisms develop during the period and within the zone of transgene expression. We present evidence that these dysraphisms result from an inhibition of neuropore closure and a stimulation of secondary neurulation. After transgene expression ceases, the spinal dysraphisms are progressively resolved and the neonatal animals, while showing signs of scarring and tissue resorption, have a closed vertebral column. The multiple spinal cords remain but are enclosed in a single spinal column as in the human diastematomyelia. The animals live a normal life time, are fertile and do not exhibit any obvious weakness or motor disabilities.

Neurofilament-M interacts with the D1 dopamine receptor to regulate cell surface expression and desensitization.

We used the yeast two-hybrid assay to identify novel proteins that interact with the D(1) dopamine receptor. The third cytoplasmic loop (residues 217-273) of the rat D(1) receptor was used as bait to identify clones encoding interacting proteins from a rat brain cDNA library. This identified two clones encoding the C terminus of rat neurofilament-M (NF-M) (residues 782-846). The NF-M clone did not interact with the third cytoplasmic loops of the rat D(2), D(3), or D(4) receptors, but showed weak interaction with that of the D(5) receptor. Coexpression of full-length NF-M with the D(1) receptor in HEK-293 cells resulted in >50% reduction of receptor binding accompanied by a reduction in D(1) receptor-mediated cAMP accumulation. NF-M had no effect on the expression of other dopamine receptor subtypes. Using a D(1) receptor-green fluorescent protein chimera and confocal fluorescence microscopy, we found that NF-M reduced D(1) receptor expression at the cell surface and promoted accumulation of the receptor in the cytosol. Interestingly, the D(1) receptors that were expressed at the cell surface in the presence of NF-M were resistant to agonist-induced desensitization. Cellular colocalization of NF-M and the D(1) receptor in the rat brain was examined by epifluorescence microscopy. These experiments showed that approximately 50% of medium-sized striatal neurons expressed both proteins. Colocalization was also observed in pyramidal cells and interneurons within the frontal cortex. Similar immunohistochemical analyses using NF-M-deficient mice showed decrements in D(1) receptor expression compared with control mice. These results suggest that NF-M interacts with the D(1) receptor in vivo and may modify its expression and regulation.

Gcm1 expression defines three stages of chorio-allantoic interaction during placental development.

The formation of the labyrinth layer is a critical step of placental development. The transcription factor glial cells missing 1 (Gcm1) plays a pivotal role in labyrinth development, but the sequence of events controlling its expression has not been identified yet. Our studies presented herein show that Gcm1 expression occurs in three distinct phases during placental development, each specific to a particular stage of chorio-allantois interaction. In the first, the pre-fusion phase, Gcm1 mRNA is expressed in isolated clusters of chorionic cells, but not efficiently translated. Upon allantois-chorion fusion, the second phase, Gcm1 expression is greatly induced in clusters of chorionic cells separated by non-expressing cells and the Gcm1 mRNA is translated to protein. In the third phase, the labyrinth formation, cells expressing Gcm1 proliferate, involute in the chorionic plate and branched villi formation begins.

HUMAN MIDSIZED NEUROFILAMENT EXPRESSION IN TRANSGENIC MOUSE-DERIVED GRAFTS FACILITATES STUDY OF GRAFT-HOST INTERACTIONS IN HYPOGONADAL MICE.

Our previous studies established that targeted axonal outgrowth into the host median eminence (ME) from grafted gonadotropin-releasing hormone (GnRH) neurons is essential for stimulation of reproductive function in hypogonadal (HPG) mice homozygous for a deletion in the GnRH gene. In the current experiments transgenic mice expressing the human midsized neurofilament NF(M) were used as sources of grafts to clarify the extent of transplant-derived innervation of the host that accompanies this dramatic recovery process. Preoptic area (POA) tissue from 1- or 2-dayold transgenic pups was implanted in the third ventricle of adult male HPG mice. Polymerase chain reaction (PCR) analysis verified that each donor bore the transgene. Immunohistochemistry using a monoclonal antibody specific for human NF(M) revealed intensely immunoreactive parvicellular soma and proximal dendrites in the grafts. Interestingly, human NF(M)-positive neurons also migrated out of the graft into the host hypothalamus. In the animal with the most dramatic increase in testicular and seminal vesicle weight, human NF(M)-positive cells were observed within the host ME. In some cases, human NF(M)-positive axonal bundles were present within the wall of the third ventricle of the host as well as in the host ME. These were GnRH negative. More extensive anatomical studies will delineate the degree and patterning of axonal outgrowth. In these early studies, however, it is apparent that neuronal fiber outgrowth into the host brain is not exclusive to GnRH fibers from the preoptic area grafts. This is important information in regard to our studies of the specificity of the signals derived from the ME that may be involved in GnRH fiber targeting.