Phenotypic Characterization of the Komeda Miniature Rat Ishikawa, an Animal Model of Dwarfism Caused by a Mutation in Prkg2

The Komeda miniature rat Ishikawa (KMI) is a spontaneous animal model of dwarfism caused by a mutation in Prkg2, which encodes cGMP-dependent protein kinase type II (cGKII). This strain has been maintained as a segregating inbred strain for the mutated allele mri. In this study, we characterized the phenotype of the KMI strain, particularly growth traits, craniofacial measurements, and organ weights. The homozygous mutant (mri/mri) animals were approximately 70% to 80% of the size of normal, heterozygous (mri/+) animals in regard to body length, weight, and naso-occipital length of the calvarium, and the retroperitoneal fat of mri/mri rats was reduced greatly. In addition, among progeny of the (BN×KMI-mri/mri)F1×KMI-mri/mri backcross, animals with the KMI phenotype (mri/mri) were easily distinguished from those showing the wild-type phenotype (mri/+) by using growth traits such as body length and weight. Genetic analysis revealed that all of the backcrossed progeny exhibiting the KMI phenotype were homozygous for the KMI allele in the 1.2-cM region between D14Rat5 and D14Rat80 on chromosome 14, suggesting strongly that mri acts in a completely recessive manner. The KMI strain is the first and only rat model with a confirmed mutation in Prkg2 and is a valuable model for studying dwarfism and longitudinal growth traits in humans and for functional studies of cGKII.Abbreviations: cGKII, cGMP-dependent protein kinase type II; CNP, C-type natriuretic peptide; KMI, Komeda miniature rat IshikawaDwarfism is caused by both endocrinologic and nonendocrinologic defects. Most instances of dwarfism, including normal variants, are nonendocrinologic, and subjects retain growth hormone secretion. Although spontaneous rodent models of dwarfism with confirmed mutations have been reported—Snell dwarf mice with Pou1f1 (Pit1) mutation,¹⁴ Ames dwarf mice with Prop1 mutation,²² little mice with Ghrhr mutation,¹⁵ pygmy mice (also known as mini-mice) with Hmga2 (HMGI-C) mutation,²⁶ spontaneous dwarf rats with Gh mutation,²³ and rdw rats with Tg mutation^9,11—most of these are models of endocrinologic dwarfism. A few models of nonendocrinologic dwarfism have been produced by gene manipulation techniques, such as transgenic and knockout strategies, and include Col2a1-transgenic mice,^7,24 Col10a1-transgenic mice,¹⁰ and Fgfr3-knock-in mice.¹³A novel spontaneous dwarf mutation, miniature rat Ishikawa (mri), was discovered in a closed colony of Wistar rats at Ishikawa Animal Laboratory (Saitama, Japan) and has been maintained on the genetic background of Wistar rats. This mutant strain, previously termed Miniature Rat Ishikawa (MRI), has recently been established as a segregating inbred strain on the Wistar genetic background, designated Komeda Miniature rat Ishikawa (KMI). The breeding record suggested that the mutation was inherited in an autosomal recessive mode. KMI rats show no abnormality in the basal amounts or distribution of several hormones, including growth hormone, luteinizing hormone, follicle-stimulating hormone, prolactin, thyroid-stimulating hormone, and adrenocorticotropic hormone, but growth hormone response to growth hormone releasing hormone is decreased.²¹Using positional candidate cloning of mri, we recently identified a deletion mutation in Prkg2, which encodes cGMP-dependent protein kinase type II (cGKII), and clarified a role of cGKII as a molecular switch that couples cessation of proliferation and the start of hypertrophic differentiation of chondrocytes.² Longitudinal skeletal growth is achieved by endochondral ossification in the growth plate, in which chondrocyte hypertrophic differentiation is an important step. Due to the impaired coupling of proliferation and hypertrophic differentiation in the growth plate chondrocytes, homozygous mutant (mri/mri) animals show longitudinal growth retardation.In this study, we further characterize the phenotype of the KMI strain, including body length, body weight, organ weight, and craniofacial measurements. Furthermore, we describe phenotypic characteristics of the progeny produced from the (BN×KMI-mri/mri)F1×KMI-mri/mri backcross and provide updated genetic, physical, and comparative maps of the mri region.