Regional mapping of the human No. 1 and X chromosome in interspecific cell hybrids using an X/1 translocation.

Fibroblasts from a carrier of an X/1 translocation, 46,XY,t(X;1)(q28;q31), were fused with Chinese hamster cells. The resulting hybrids were analyzed for human No. 1 and X-chromosome markers. The data indicate that the loci for PGM1, PGD, PPH, and GuK1 are situated either in the long arm proximal to a break point in band 1q31 or in the short arm. The loci for Pep-C, FH, and GuK1 are located distal to the break point. HPRT and G6PD are probably situated distal to a break point in band q28 of the X chromosome; alpha-Gal A is situated proximal to the break point, either on the long or short arm of the chromosome.     

Assignment of peptidase S (PEPS) to chromosome 4 in man using somatic cell hybrids

Summary A starch gel electrophoretic procedure is described that resolves peptidase S (PEPS) as well as the peptidases A, B, and C in man-rodent, rodent-rodent, and primate-rodent interspecific somatic cell hybrids. The interspecific PEPS cell hybrid phenotype can be resolved into a pattern which suggests that PEPS is composed of five or six identical subunits.Results are presented supporting assignment of the PEPS locus to chromosome 4 in man using man-mouse and man-Chinese hamster somatic cell hybrids. Human genes coding for peptidases A, B, C, and D were assigned to chromosome 18, 12, 1, and 19, respectively, confirming previous assignments. These somatic cell genetic data demonstrate the independent genetic control of the several human peptidases.This work was supported by NIH grants GM 20454 and HD 05196.     

Mapping genetic markers on human chromosome 19 using subchromosomal fragments in somatic cell hybrids

A series of mouse-human somatic cell hybrid lines (WILF) were derived from a hybrid that was originally thought to have chromosome 19 as its only human chromosome. In situ hybridization has been used to assess the amount of human material present in the different lines. All appear to contain different numbers of human chromosome fragments. A series of X-chromosome-specific DNA sequences hybridized against DNA from the lines revealed that material from the X long arm is present in several cases. Chromosome 19-specific DNA sequences used in a similar way show that fragmentation of this this chromosome has occurred with subsequent segregation of the fragments in different lines. The localization of these markers to various regions of chromosome 19, and their relation to the fragments observed in the WILF lines, is discussed.     

Normal X chromosome induced reversion in the direction of chromosome segregation in mouse-Chinese hamster somatic cell hybrids

The effect of a normal mouse X chromosome on the chromosome segregation of mouse-Chinese hamster somatic cell hybrids was determined by (i) producing hybrids between the mouse sarcoma line CMS4 and a microcell hybrid (mfe4) of the hamster line E36, containing a mouse X chromosome from a normal cell; (ii) isolating hybrids between CMS4 and a 6-thioguanine selected (X minus) mfe4 subpopulation; (iii) comparing the direction of segregation in the two sets of hybrids. It was found that the normal X chromosome, like the X chromosomes from two MCA-transformed sarcoma lines reported previously [9], has the ability to switch the chromosome segregation of mouse-Chinese hamster somatic cell hybrids. We conclude that the reversal in chromosome segregation is mediated by factors located on the X chromosome. We designate these genetic elements as segregation reversal genes or sr genes.     

X chromosome-induced reversion of chromosome segregation in mouse/Chinese hamster somatic cell hybrids : Cellular recognition of native and foreign X chromosomes

The direction of chromosome loss in two sets of mouse-Chinese hamster hybrids was compared with the direction of segregation of the same hybrids, to which an additional X chromosome derived from either of the mouse sarcoma lines MethAa, MethAs, or CMS4, was introduced at the time of the fusion. The addition of the X chromosome was carried out by substituting in place of the Chinese hamster parent a mouse X containing microcell hybrid of the latter. It was found that the addition of an X chromosome reverses the direction of chromosome segregation, but it can do so only if the mouse parent in the hybridization is different from the line from which the X originated. The possible reasons for recognition by the cells of a native and a foreign X are discussed. The existence of a multigene family on the X chromosome, involved in this recognition, is proposed.     

Y to X translocation in man

Summary Five new cases are added to the single published instance of Yq to Xp translocation (X_t) in man. It is shown that the anomaly can occur as a mutational event during meiosis, and can be inherited from a parent, but also that it can arise in a 47,XXY embryo. In individuals with 46,XX_t karyotype the gonadal development, sexual differentiation, gonadal function and fertility are within the range of normal females. They do not present overt or discrete sings of virilisation. However, somatic stigmata, and more specifically short stature, are present in all patients. There is no uniform pattern of X_t inactivation which varies from random to apparently preferential inactivation. This phenomenon may be important for the better understanding of X-inactivation which for the X_t the authors believe is random but followed by differential proliferation of the resulting two types of cells.Aided by grant 20 122 F.G.W.O. — Belgium.     

Quantitative analysis of human chromosome segregation in man-mouse somatic cell hybrids.

The presumed random and independent process of human chromosome segregation in man-mouse somatic cell hybrids was studied. The results of chromosome analysis on 196 cells from 15 related hybrid strains have provided the first convincing evidence that segregation of human chromosomes can be nonindependent and often concordant. Different human chromosomes were not retained with equal frequency in these hybrid clones. Some were present in 80% of all the cells, whereas others appeared in less than 10% of the same cells. Linear regression analysis was used to test for correlation of the frequencies of all pair-wise combinations of human chromosomes present in these hybrid clones. Twenty-two of 136 possible correlations were statistically significant, indicating that concordant segregation of particular pairs of human chromosomes is a rather frequent occurrence.     

Toward a complete linkage map of the human X chromosome: regional assignment of 16 cloned single-copy DNA sequences employing a panel of somatic cell hybrids.

Closely linked restriction fragment length polymorphisms (RFLPs) are potentially useful as diagnostic markers of genetic defects, and, in principle, RFLPs can be employed to construct a complete linkage map of the human genome. On the X chromosome, linkage studies are particularly rewarding because in man more than 120 X-linked genes are known. Thus, it is probable that each X-specific RFLP will be of use as a genetic marker of one or several X-linked disorders. To facilitate the search for closely linked RFLPs, we have regionally assigned 16 cloned DNA sequences to various portions of the human X chromosome, employing a large panel of somatic cell hybrids. These probes have been used to correlate genetic and physical distances on Xp, and it can be extrapolated from these data that the number and distribution of available Xq sequences will also suffice to span the long arm of the X chromosome.     

Assignment of genes to the human X chromosome by the two-dimensional electrophoretic analysis of total cell proteins from rodent-human somatic cell hybrids.

The technique of two-dimensional (2-D) gel electrophoresis was sued to identify five human X-linked gene products in crude cell extracts of mouse-human and Chinese hamster-human somatic cell hybrids. The human origin of these five polypeptides was demonstrated by their comigration with human fibroblast proteins and their failure to comigrate with polypeptides in extracts from the mouse or hamster parental cells. All five polypeptides were present in extracts of rodent-human hybrids that contained a human X chromosome, but were not found in extracts of cells that lacked a human X chromosome. Chromosome analysis of the hybrid clones revealed that the human X chromosome is both necessary and sufficient for the expression of the five polypeptides, designated pX-24, pX-27, pX-37, pX-40, and pX-56. pX-56 can be identified as the human X-linked enzyme glucose-6-phosphate dehydrogenase (G6PD) (E.C.1.1.1.49), while polypeptides pX-24, pX-27, pX-37 and pX-40 have molecular properties unlike those of known human X-linked gene products. pX-24 appears to be a membrane-bound protein that maps to the distal portion of the long arm of the human X chromosome, while pX-27, pX-37, and pX-40 are soluble proteins that map to the proximal long arm or to the short arm of the human X chromosome. 2-D gel electrophoretic analysis of extracts from somatic cell hybrids provides a general method for identifying polypeptides in crude cell extracts coded for by any specific chromosome and can be used to study primary gene products not previously amenable to genetic analysis.     

Assignment of PGM3 to the long arm of human chromosome 6. Studies using Chinese hamster X human cell hybrids containing a human 6/15 translocation

Hybrids derived from the fusion of thymidine kinase deficient Chinese hamster cells and human cells carrying a 6/15 translocation, 46,XX,t(6;15)(cen;p13), were analyzed for the expression of human PGM3, GLO and ME1. The results show that PGM3 and ME1 are on the long arm and GLO is on the short arm of human chromosomes 6.     

Assignment of the catechol-O-methyltransferase gene to human chromosome 22 in somatic cell hybrids

Summary Catechol-O-methyltransferase (COMT) plays an important role in the inactivation of catecholamines. It has been demonstrated that erythrocyte COMT activity is genetically determined and controlled by a major autosomal locus with two alleles. The recent development of a method which allows the detection of COMT isozymes directly in autoradiozymograms has provided the means to investigate the chromosome location of the gene by using somatic cell hybrids. We have found that a single form of the COMT enzyme is expressed in several mouse-human fibroblast cell lines. The data obtained from the segregation analysis of the COMT enzyme in these hybrids and their subclones have provided evidence for the location of a major gene for COMT activity on human chromosome 22.