Wilma L. Neuman

Cloning of cDNAs for human phosphoribosylpyrophosphate synthetases 1 and 2 and X chromosome localization of PRPS1 and PRPS2 genes

Cloned cDNAs representing the entire, homologous (80%) translated sequences of human phosphoribosylpyrophosphate synthetase (PRS) 1 and PRS 2 cDNAs were utilized as probes to localize the corresponding human PRPS1 and PRPS2 genes, previously reported to be X chromosome linked. PRPS1 and PRPS2 loci mapped to the intervals Xq22-q24 and Xp22.2-p22.3, respectively, using a combination of in situ chromosomal hybridization and human x rodent somatic cell panel genomic DNA hybridization analyses. A PRPS1-related gene or pseudogene (PRPS1L2) was also identified using in situ chromosomal hybridization at 9q33-q34. Human HPRT and PRPS1 loci are not closely linked. Despite marked cDNA and deduced amino acid sequence homology, human PRS 1 and PRS 2 isoforms are encoded by genes widely separated on the X chromosome.

Report of the second international workshop on human chromosome 5 mapping

This report describes the accomplishments of the Second International Workshop on Human Chromosome 5 as was held May 11--13,1992 at the University of Chicago. Included in the report are abstract of individual presentations and a consensus map of the chromosome.

Physical and genetic map of 5q31: use of fluorescence in situ hybridization data to identify errors in the CEPH database

Chromosome 5, band q31, contains the genes responsible for a number of interesting genetic and malignant diseases, as well as many cloned genes. To prepare a high-resolution map of this region, eight

A physical and genetic linkage map of the distal long arm of human chromosome 5

By in situ hybridization of probes for three cloned genes and eight genetically-linked polymorphic DNA markers, we have prepared a physical map of the distal long arm of chromosome 5. These results, together with the localizations of 11 genes and the genetic linkage map reported previously by us and by other investigators, represent a map that spans 55 cM.

Characterization of yeast artificial chromosomes containing interleukin genes on human chromosome 5

To understand better the organization and linkage of the interleukin genes, IL4 and IL5, we prepared long-range restriction maps of five yeast artificial chromosomes (YACs) containing IL5. We determined that IL4 and IL5 are within 100-170 kb, and that the regions surrounding these genes contain several GC-rich areas. Fluorescence in situ chromosomal analysis demonstrated that three of the five YAC clones contain non-contiguous genomic sequences originating from multiple human chromosomes.

Somatic cell hybrid mapping of human chromosome band 5q31: A region important to hematopoiesis

As a means of characterizing the distal long arm of chromosome 5, in particular, the region spanning 5q23-->q31, we analyzed somatic cell hybrids prepared from cells with overlapping chromosomal rearrangements. In one hybrid, the derivative chromosome 5 from a patient with acute myeloid leukemia (AML) de novo, whose bone marrow cells had a balanced translocation, t(5;7)(q31;q22), involving chromosome band 5q31, was isolated in a somatic cell hybrid (B294). In addition, we prepared somatic cell hybrids from a lymphoblastoid cell line (CC) derived from a patient who has a constitutional interstitial deletion of chromosome 5 spanning 5q23.1-->q31.1. By a combination of Southern hybridization analysis and fluorescent in situ hybridization, we constructed a map dividing 5q23-->q31 into four regions. We can assign genes to these regions and relate them to anonymous RFLP markers that have been genetically mapped.

Physical localization of 70 polymorphic markers to human chromosome 5 by fluorescence in situ hybridization

We used fluorescence in situ hybridization (FISH) to prepare a cytogenetic framework map of 21 polymorphic markers that had been used previously to construct a genetic linkage anchor map of chromosome 5. In addition, we localized 49 other markers that have been genotyped on CEPH families. This study demonstrates that FISH can be used to confirm genetic linkage data, and that it can provide a means of determining the cytogenetic locations and relative order of markers whose order could not be assigned by genetic linkage analysis alone. The cytogenetic map prepared by FISH may help to identify probes of interest for regional mapping studies.