The mouse has transcended its humble role as a tiny part of the ecosystem to become a prominent player in the war against human ailments such as cancer, congenital malformations as well as neurological, metabolic, immunological, degenerative and age-related diseases. While early embryologists and teratologists used the rat and the rabbit as mammalian models, these were overshadowed by the mouse following the advent of mouse genetics, the generation of inbred strains and the availability of scores of spontaneous, chemically and radiation-induced mouse mutants. Added to these advantages are the facts that mice have relatively short generation times, are prolific, small in size, and can be maintained in a cost-effective way. In the last decade of the 20th century, development of innumerable and increasingly innovative and powerful molecular and genetic tools enabling genetic manipulation of the mouse, combined later on with the completion of the mouse genome sequence, catapulted the use of the mouse in biomedical research to a new era. In parallel, mouse strain repositories and information resources, such as sequence, gene expression and phenotype databases, emerged and continue to facilitate the endeavor of scientific and industrial communities. In addition to mice with spontaneous mutations, thousands of mouse models of human diseases have been generated by different methods, including transgenesis, ethylnitrosourea (ENU)- or transposon-induced mutagenesis, gene-targeting and gene-trapping technologies. Work by international consortia is underway with the challenging goal of disabling the 20,000 protein encoding genes in the mouse genome. Recently, a novel and powerful technology enabled, so far, the generation of more than 9,000 reporter (lacZ)-tagged conditional alleles in mouse embryonic stem cell lines, and is aiming at generating reporter-tagged conditional mutations in all murine protein-coding genes within the next few years [1].

Lip and palate clefting results from disruptions impacting on cellular migration, proliferation, programmed cell death (apoptosis), extracellular matrix deposition and/or morphogenetic movements. All of these developmental events are crucial during the formation of lip and palate primordia. In contrast to development of the upper lip and primary palate, development of the secondary palate takes place in conjunction with growth and differentiation of other structures in the head and oral cavity, including the craniofacial skeleton and tongue. Therefore, clefting of the secondary palate may be secondary to defects in these structures, especially if the gene is not expressed in the primordia of the palate proper [4, 5, 8]. However, CP can also be associated either with intrinsic disruptions within the palate proper or by a combination of both primary biological alterations within the palatal shelves and defects in other cranial structures [5, 9]. In view of the striking external differences between humans and mice, a non-specialist would question the usefulness of the mouse in CL and CP research. However, during early craniofacial development, mouse and the human embryos bear a striking resemblance and are essentially of similar sizes. In addition, development of the lip and palate are basically similar in the two species. More importantly and notwithstanding the fact that mice and humans share around 99% of their genes [5], numerous genes that have been incriminated as causal factors in human orofacial clefting also engender clefting in mice and vice versa [5].

In addition to the availability of different methods for the generation of mice, which model an array of human diseases, including congenital malformations, complementary techniques and tools for mouse studies are abundant and are becoming more and more sophisticated. In developmental biology, methods such as whole-mount staining of embryos or organ primordia for the visualization of transcripts, small molecules, and endogenous or reporter proteins are particularly informative. Similarly, skeletal preparations with alcian blue and alizarin red staining provide clues about the extent of defects in craniofacial skeletal elements. These can be combined with 3...