However, no hint of measurable linkage was found in six pedigrees segregating for G6PD and the Renpenning syndrome or other unspecified types of X-linked mental retardation.
We report on a family with 4 affected males in 3 generations with a previously unreported X-linked mental retardation/multiple congenital anomaly (XLMR/MCA) syndrome.
Golabi and Rosen (1984) have reported on a new X-linked mental retardation/multiple congenital anomalies (XLMR/MCA) syndrome of pre- and postnatal overgrowth, characteristic "coarse" facial appearance with macrostomia, midline groove of tongue, lower alveolar ridge and lip, submucous cleft of palate, supernumerary nipples, intestinal anomalies, supernumerary pair of ribs, anomalies of sacrum and tailbone, hypoplastic index fingernails, postaxial polydactyly and other digital anomalies.
We have previously reported a common type of X-linked mental retardation associated with an inducible fragile site at Xq27-Xq28 segregates in a close linkage relationship with a G6PD variant, but the relative position of G6PD with respect to the fragile site has not yet been established.
These observations and the well-established knowledge that the genes for Deutan and Protan colorblindness are closely linked to G6PD, but segregate independently of factor IX deficiency, suggest that the fragile site associated with this type of X-linked mental retardation occurs in a region prone to high frequency of meiotic recombination.
Our data therefore indicate that the gene responsible for fragile X-linked mental retardation is not as tightly linked to the factor IX gene as the previously published data may suggest.
In order to obtain a model cell system suitable for studying the mechanism of expression of the fragile X site, interspecific somatic cell hybrids were constructed by cell fusion between human skin fibroblasts derived from a male patient with fragile X-linked mental retardation and thymidylate synthase-negative mouse mutant cells.
Gene localization was determined by linkage analysis in 5 families with non-specific X-linked mental retardation (MRX) and were MRX1, Xp11.4-q21.31; MRX10, Xp21.3-p11.4; MRX11, Xp21.3-p11.22; MRX12, Xp21.3-q21.1; and MRX13, Xp22.3-q21.22.
Gene localization was determined by linkage analysis in 5 families with non-specific X-linked mental retardation (MRX) and were MRX1, Xp11.4-q21.31; MRX10, Xp21.3-p11.4; MRX11, Xp21.3-p11.22; MRX12, Xp21.3-q21.1; and MRX13, Xp22.3-q21.22.
Gene localization was determined by linkage analysis in 5 families with non-specific X-linked mental retardation (MRX) and were MRX1, Xp11.4-q21.31; MRX10, Xp21.3-p11.4; MRX11, Xp21.3-p11.22; MRX12, Xp21.3-q21.1; and MRX13, Xp22.3-q21.22.
This has enabled us to assign the DFN3 gene and a gene for nonspecific XLMR to an interval that encompasses the locus DXS232 and that is flanked by DXS26 and DXS121.
Gene localization was determined by linkage analysis in 5 families with non-specific X-linked mental retardation (MRX) and were MRX1, Xp11.4-q21.31; MRX10, Xp21.3-p11.4; MRX11, Xp21.3-p11.22; MRX12, Xp21.3-q21.1; and MRX13, Xp22.3-q21.22.