A second-generation genetic linkage map of the domestic dog, Canis familiaris.

Purebred strains, pronounced phenotypic variation, and a high incidence of heritable disease make the domestic dog uniquely suited to complement genetic analyses in humans and mice. A comprehensive genetic linkage map would afford many opportunities in dogs, ranging from the positional cloning of disease genes to the dissection of quantitative differences in size, shape, and behavior. Here we report a canine linkage map with the number of mapped loci expanded to 276 and 10-cM coverage extended to 75-90% of the genome. Most of the 38 canine autosomes are likely represented in the collection of 39 autosomal linkage groups. Eight markers were sufficiently informative to detect linkage at distances of 10-13 cM, yet remained unlinked to any other marker. Taken together, the results suggested a genome size of about 27 M. As in other species, the genetic length varied between sexes, with the female autosomal distance being approximately 1.4-fold greater than that of male meioses. Fifteen markers anchored well-described genes on the map, thereby serving as landmarks for comparative mapping in dogs. We discuss the utility of the current map and outline steps necessary for future map improvement.

Exclusion probabilities of 22 bovine microsatellite markers in fluorescent multiplexes for semiautomated parentage testing.

Six multiplexes developed for semiautomated fluorescence genotyping were evaluated for parentage testing. These multiplexes contained primer pairs for the amplification of 22 microsatellites on 17 bovine autosomes. Exclusion probabilities were determined from genotypes of 1022 Holstein cattle and 311 beef cattle belonging to five breeds. Two cases were considered: case 1, genotypes are known for an alleged parent and an offspring but genotypes of a confirmed parent are unknown; and case 2, genotypes are known for an alleged parent, a confirmed parent and an offspring. If the alleged parent is not the true parent, then the 22 markers will exclude the alleged parent with a probability of > 0.9986 for case 1 and with a probability of > 0.99999 for case 2. On the basis of these exclusion probabilities, the probability that an alleged parent will be falsely included as a parent is in the range of 1/716 to 1/2845 for case 1 and 1/1.2 million to 1/159753 for case 2. In addition to these results, a rapid and efficient non-organic method for extraction of DNA from semen is described.

Evidence for a susceptibility locus for schizophrenia on chromosome 6pter-p22.

We have performed linkage analysis in 186 multiplex families to search for genes that predispose to schizophrenia. Under a model with partially dominant inheritance, moderately broad disease definition and assuming locus homogeneity, a lod score of 3.2 was obtained for D6S260 on chromosome 6p23. A multipoint lod score of 3.9 (P = 2.3 x 10(-5)) was achieved when the F13A1 and D6S260 loci were analysed, allowing for locus heterogeneity. Adjusted for testing of multiple models, the multipoint lod score of 3.9 under heterogeneity has a genome wide significance of between 5-8%. The nonparametric affected pedigree member test provided results (P = 3 x 10(-4)) also supporting this finding. Our findings provide supportive evidence for a susceptibility locus for schizophrenia on distal chromosome 6p, and support a model of locus heterogeneity.

Application of automated DNA sizing technology for genotyping microsatellite loci.

Highly polymorphic microsatellite loci offer great promise for gene mapping studies, but fulfillment of this potential will require substantial improvements in methods for accurate and efficient genotyping. Here, we report a genotyping method based on fluorescently labeled PCR primers and size characterization of PCR products using an automated DNA fragment analyzer. We capitalize on the availability of three distinct fluorescent dyes to label uniquely loci that overlap in size, and this innovation increases by threefold the number of loci that can be analyzed simultaneously. We label size standards with a fourth dye and combine these with the microsatellite PCR products in each gel lane. Computer programs provide very rapid and accurate sizing of microsatellite alleles and efficient data management. In addition, fluorescence signals are linear over a much greater range of intensity than conventional autoradiography. This facilitates multiplexing of loci (since signal intensities often vary greatly) and helps distinguish major peaks from artifacts, thereby improving genotyping accuracy.

The use of fluorescence detection and internal lane standards to size PCR products automatically.

We have developed chemical procedures, optical and electrophoretic instrumentation and computer software automate the analysis of polymerase chain reaction (PCR) products. DNA molecules labeled with up to four different fluorescent dyes are analyzed within a single electrophoresis gel lane. A size calibration curve is created for each electrophoresis lane from the electrophoretogram of uniquely labeled DNA fragments belonging to an internal lane standard that co-electrophoreses with the PCR products. The unknown molecular lengths of PCR products are automatically calculated from the calibration curve. Data from control experiments with DNA segments of known molecular length demonstrate the accuracy and precision of such sizing. This system has been applied to the analysis of PCR products for research in the areas of human identification, genetic mapping and genetic disease.

Genetic determinants for catabolite induction of antibiotic biosynthesis in Pseudomonas fluorescens HV37a.

Antibiotic biosynthesis is regulated by glucose in Pseudomonas fluorescens HV37a. Fusions between antibiotic biosynthetic operons (afu operons) and the Escherichia coli lac operon were isolated to evaluate the genetic determinants for the regulation of antibiotic biosynthesis. Four afu transcriptional units were defined, afuE, afuR, afuAB, and afuP. The afuE and afuR transcripts were promoted divergently at one locus and were catabolite induced, by 250-fold and 5-fold, respectively; the afuAB and afuP transcriptional units were not linked to the others and were not catabolite induced. Thus, regulation of afuE and afuR operon transcription is apparently the mechanism whereby glucose regulates antibiotic biosynthesis. Catabolite induction of the afuE and afuR transcriptional unit was dependent on the products of the afuA, afuB, and afuP genes. Expression of the afuE transcriptional unit was altered quantitatively in afuE mutants. Apparently the afuE transcriptional unit is regulated, at least in part, by its own gene products. Under inducing conditions, expression of the afuE, afuR, and afuP transcriptional units increased rapidly during a 6-h period.

Molecular cloning of genetic determinants for inhibition of fungal growth by a fluorescent pseudomonad.

Pseudomonas fluorescens HV37a inhibits growth of the fungus Pythium ultimum in vitro. Optimal inhibition is observed on potato dextrose agar, a rich medium. Mutations eliminating fungal inhibition were obtained after mutagenesis with N-methyl-N'-nitro-N-nitrosoguanidine. Mutants were classified by cosynthesis and three groups were distinguished, indicating that a minimum of three genes are required for fungal inhibition. Cosmids that contain wild-type alleles of the genes were identified in an HV37a genomic library by complementation of the respective mutants. This analysis indicated that three distinct genomic regions were required for fungal inhibition. The cosmids containing these loci were mapped by transposon insertion mutagenesis. Two of the cosmids were found to contain at least two genes each. Therefore, at least five genes in HV37a function as determinants of fungal inhibition.