Cross-modal innervation of primary visual cortex by auditory fibers in congenitally anophthalmic mice.

Auditory-visual cross-modal innervation was examined in control (sighted, ZRDCT-N) and congenitally anophthalmic (eyeless, ZRDCT-AN) mice using electrophysiological recording and pathway tracing with carbocyanine dyes. Electrophysiological data demonstrate that the primary visual cortex of congenitally eyeless, blind, mice receives auditory stimuli. Neuroanatomical data demonstrate a direct connection between the inferior colliculus (IC) and visual cortex.

Physiological and anatomical properties of the suprachiasmatic nucleus of an anophthalmic mouse.

Congenitally anophthalmic mice (ZRDCT-AN) have circadian rhythms which 'free-run' and are not light modulated. Their rhythms differ from those of controls in: duration of circadian period, length of active phase, and pattern/intensity of activity. Three different populations have been described based upon wheel-running: rhythmic with stable period, rhythmic with unstable period and arrhythmic.

The eyeless mouse mutation (ey1) removes an alternative start codon from the Rx/rax homeobox gene.

The eyeless inbred mouse strain ZRDCT has long served as a spontaneous model for human anophthalmia and the evolutionary reduction of eyes that has occurred in some naturally blind mammals. ZRDCT mice have orbits but lack eyes and optic tracts and have hypothalamic abnormalities. Segregation data suggest that a small number of interacting genes are responsible, including at least one major recessive locus, ey1.

The relationship between circadian rhythmicity and vasoactive intestinal polypeptide in the suprachiasmatic nucleus of congenitally anophthalmic mice.

To date, the search for the clock component that is both necessary and sufficient for generation of circadian rhythms has relied primarily on experimental interventions such as lesions and transplantation of fetal SCN. While these approaches have been fruitful, lesions disrupt adjacent host tissue and fiber pathways, and donor tissue is likewise subject to trauma during harvest and transplantation. The current investigation has used congenitally anophthalmic (eyeless) mice to ask whether VIP-IR SCN neurons are necessary and sufficient for generation of circadian rhythms.