Genetic analysis of alcohol intake in recombinant inbred and congenic strains derived from A/J and C57BL/6J progenitors

The objective of the present study was to map quantitative trait loci (QTL) for alcohol intake using A × B/B × A recombinant inbred (RI) and AcB/BcA recombinant congenic (RC) strains of mice that were independently derived from the A/J and C57BL/6J progenitors. Mice were screened for levels of alcohol consumption with four days of forced exposure to alcohol, followed by three weeks of free choice between water and a 10% alcohol solution. Alcohol consumption data previously collected for 27 A × B/B × A RI strains were reanalyzed using a larger marker set and composite interval mapping. The reanalysis found markers on Chromosome 2 (D2Mit74, 107 cM) (males and females) and on Chromosome 11 (Pmv22, 8 cM) (females only) that exceeded the threshold for significant loci, and found suggestive loci (in males) on Chromosomes 10 (D10 Mit126, 21 cM), 12 (D12Mit37, 1 cM), 15 (Pdgfb, 46.8 cM), and 16 (D16Mit125, 29 cM). An additional suggestive locus was identified in female RI mice on Chromosome 11 (D11Mit120, 47.5 cM). Composite interval mapping (CIM) analysis indicated that there was a significant association between loci at Pdgfb and D2Mit74 in both males and females. Analysis of the AcB/BcA RC strains identified 11 QTL on Chromosomes 2, 3, 5,6, 7, 8, 9, 10, 12, 13, and 15. QTL on Chromosomes 7, 10, 12, and 15 were identified in both the A × B/B × A RI and AcB/BcA RC strains of mice. Additional QTLs identified on Chromosomes 2, 3, 7, 11, and 15 overlap with those previously identified in the literature using strains of mice with a C57BL/6J progenitor.     

Genetic characterization of a new set of recombinant inbred lines (LGXSM) formed from the intercross of SM/J and LG/J inbred mouse strains

A new set of LGXSM recombinant inbred (RI) strains is presented. The RI strain panel consists of 18 remaining strains of the original 55 founding strains. Strain characterization is based on 506 polymorphic microsatellites and 4289 single nucleotide polymorphisms (SNPs) distributed across the genome. Average microsatellite intermarker distance is 4.80 ± 4.84 Mb or 2.91 ± 3.21 F₂ cM. SNPs are more densely spaced at 0.57 ± 1.27 Mb. Ninety-five percent of all microsatellite intermarker intervals are separated by less than 15.00 Mb or 8.50 F₂ cM, while 95% of the SNPs are less than 0.95 Mb apart. Strains show expected low levels of nonsyntenic association among loci and complete genomic independence. During inbreeding, the RI strains went through strong natural selection on the agouti locus on Chromosome 2, especially when the epistatically interacting tyrosinase locus on Chromosome 7 carried the wild-type allele. The LG/J and SM/J strains differ in a large number of biomedically important traits, and they and their intercross progeny have been used in multiple mapping studies. The LG×SM RI strain panel provides a powerful new resource for mapping the genetic bases of complex traits and should prove to be of great biomedical utility in modeling complex human diseases such as obesity and diabetes. Electronic Supplementary Material Electronic Supplementary material is available for this article at and accessible for authorised users.     

A new framework marker-based linkage map and SDPs for the Rat HXB/BXH strain set

A new contiguous genetic linkage map of the HXB/BXH set of rat recombinant inbred (RI) strains was constructed to enhance QTL mapping power and precision, and thereby make the RI strain set a better genomics resource. The HXB/BXH rat RI strains were developed from a cross between the hypertensive SHR/OlaIpcv and normotensive BN-Lx/Cub rat strains and have been shown useful for identifying quantitative trait loci (QTL) for a variety of cardiovascular, metabolic, and behavioral phenotypes. In the current analysis, the DNAs from 31 existing strains, 1 substrain, and 4 extinct strains were genotyped for a selection of polymorphic microsatellite marker loci, predominantly polymorphic framework markers from high-density integrated rat genome maps. The resulting linkage map consists of 245 microsatellite markers spanning a total length of 1789 cM with an average inter-marker distance of ~8.0 cM. This map covers the rat genome contiguously and completely with the exception of two locations on Chromosomes (Chrs) 11 and 16. The new genotypic information obtained also permitted further genetic characterization of the RI strain set including strain independence, genetic similarity among the individual strains, and non-syntenic associations between loci.     

Confidence limits for estimates of gene linkage based on analysis of recombinant inbred strains

Recombinant inbred (RI) strains are extremely useful for genetic mapping. This paper presents a simple method for determining confidence intervals for linkage estimates based on analysis of RI strains. The results show that such confidence intervals are usually large with the currently available numbers of RI strains. Therefore, map positions based only on analysis of RI strains should be interpreted with caution. To facilitate interpretation of linkage data derived from RI strains, a table is presented giving the 95 percent and 99 percent confidence intervals for all possible linkages detected with up to 45 RI strains.     

The genetic structure of recombinant inbred mice: High-resolution consensus maps for complex trait analysis

Background

Recombinant inbred (RI) strains of mice are an important resource used to map and analyze complex traits. They have proved particularly effective in multidisciplinary genetic studies. Widespread use of RI strains has been hampered by their modest numbers and by the difficulty of combining results derived from different RI sets.

Results

We have increased the density of typed microsatellite markers 2- to 5-fold in each of several major RI sets that share C57BL/6 as a parental strain (AXB, BXA, BXD, BXH, and CXB). A common set of 490 markers was genotyped in just over 100 RI strains. Genotypes of another ~1100 microsatellites were generated, collected, and error checked in one or more RI sets. Consensus RI maps that integrate genotypes of ~1600 microsatellite loci were assembled. The genomes of individual strains typically incorporate 45-55 recombination breakpoints. The collected RI set - termed the BXN set - contains approximately 5000 breakpoints. The distribution of recombinations approximates a Poisson distribution and distances between breakpoints average about 0.5 cM. Locations of most breakpoints have been defined with a precision of < 2 cM. Genotypes deviate from Hardy-Weinberg equilibrium in only a small number of intervals.

Conclusions

Consensus maps derived from RI strains conform almost precisely with theoretical expectation and are close to the length predicted by the Haldane-Waddington equation (X3.6 for a 2-3 cM interval between markers). Non-syntenic associations among different chromosomes introduce predictable distortions in QTL data sets that can be partly corrected using two-locus correlation matrices.     

Genetic mapping of the integrin alpha 1 gene (Vla1) to mouse chromosome 13.

The integrin alpha 1 chain (Vla1) associates with the beta 1 chain to form a heterodimer that functions as a dual laminin/collagen receptor in neural cells and hematopoietic cells. We have used an interspecies backcross gene-mapping technique to map the Vla1 gene to the distal end of chromosome 13 in the mouse genome. The Vla1 locus is located 3.5 cM distal to Ctla-3 and 7.8 cM distal to Htrla. We have further characterized this locus in recombinant inbred (RI) mice by examining the strain distribution patterns of nine genomic DNA restriction fragment length variants detected with alpha 1 cDNA probes. The RI gene mapping did not show linkage to previously mapped genes or mutants in the AXB, BXA, or AKXD RI sets and therefore defines a new genetic marker for the distal end of chromosome 13 in these RI sets.     

Localization of the cryptdin locus on mouse chromosome 8

Cryptdin is a defensin-related peptide, and its mRNA accumulates to high abundance in epithelial cells of intestinal crypts beginning in the second week of postnatal development. The cryptdin (Defcr) locus was assigned to mouse chromosome 8 by Southern blotting of DNAs from mouse/hamster somatic hybrid cell lines. Analysis of somatic hybrid DNAs for mouse-specific restriction fragments showed zero discordance and perfect concordance with chromosome 8. The Defcr locus was localized on chromosome 8 by analysis of DNAs from recombinant inbred (RI) strains of mice after identification of three potential Defcr alleles based on restriction fragment length polymorphisms (RFLPs) in inbred strains. The strain distribution patterns of the Defcr locus were compared with those of chromosome 8 markers in five panels of RI strains. Analysis of cosegregation of Defcr with xenotropic proviral locus Xmv-26 and additional loci confirmed the chromosomal assignment and showed that Defcr is on proximal chromosome 8 within approximately 6 (1.3 to 21.3) cM of Xmv-26. The mouse Defcr locus and the human defensin gene(s) located on chromosome 8p23 appear to map to homologous regions.     

The gene for proliferating cell nuclear antigen (Pcna) maps to mouse Chromosome 2

The structural gene for proliferating cell nuclear antigen (Pcna) has been mapped to mouse Chromosome (Chr) 2 by use of a PCR-based assay. With somatic cell hybrids, Pcna was mapped between the T(2;4)13H and T(2;4)1Sn breakpoints. An interspecific backcross was employed to map Pcna 1.9±1.3 cM distal to Il-lb. This was confirmed by mapping Pcna in the BXH recombinant inbred (RI) strains; no recombinants were seen between Il-la and Pcna. In addition, a PCNA-related sequence (Pcna-rsl) was mapped to Chr 19 in the BXH RI strains.     

The defensin-related murine CRS1C gene: expression in Paneth cells and linkage to Defcr, the cryptdin locus.

The site of defensin-related CRS1C gene expression in mouse small bowel and the chromosomal location of the CRS1C locus, Defcr-rs1, have been determined. CRS1C (cryptdin-related sequence 1C) mRNA is an abundant small intestinal sequence that exhibits extensive similarity to the prepro-coding regions of defensin mRNAs yet does not encode a defensin (A. J. Ouellette and J. C. Lualdi, 1990, J. Biol. Chem. 265: 9831-9837). Using sequence-specific probes, CRS1C mRNA was detected in Paneth cells at the base of intestinal crypts by in situ hybridization. Southern blot analysis of genomic DNAs from inbred and recombinant inbred (RI) mouse strains, also conducted with probes specific for CRS1C, showed that the CRS1C locus maps to the proximal region of Chromosome 8. In 62 RI strains, no discordancies were found between Defcr-rs1 and Defcr, the cryptdin gene. Thus, both the Defcr-rs1 and the Defcr genes are expressed in Paneth cells and both are genetically inseparable within 1.58 cM on Chromosome 8. These studies identify a second defensin-related Paneth cell gene in mice.     

Genetic regulation of the cytochrome P-450 system in Drosophila melanogaster. II. Localization of some genes regulating cytochrome P-450 activity

The localization of some genes determining the capacity for some cytochrome P-450 -dependent reactions have been studied in adult Drosophila. Strains with genetically determined high or low enzyme activities were crossed with strains carrying recessive visible markers on the chromosomes, and enzyme activities were measured in microsomes from recombinant F2 progeny. A dominantly inherited high p-nitroanisole (PNA) demethylation and biphenyl 3-hydroxylation in insecticide-resistant strains were both shown to be located around 65 cM on the second chromosome, regulated by one gene or closely linked genes. This localizes these activities to the same region as the gene responsible for the cross resistance to several classes of insecticides and a high metabolism of vinyl chloride in resistant strains. The occurrence of a regulatory gene mutation as a basis for the insecticide resistance is proposed. Hydroxylation of benzo[a]pyrene (BP) and deethylation of 7-ethoxy-coumarin seems to be determined by two third chromosome genes, at approx. 51 and 58 cM, respectively. The capacity for biphenyl 4-hydroxylation was shown to be determined by two genes on the second chromosome, one at or to the left of the gene black (48 cM) responsible for a low metabolism in strain Berlin K, and one at about 63 cM giving high formation of this metabolite in Oregon R. The latter could not be separated from the gene in insecticide-resistant strains at c:a 65 cM discussed above on the basis of the genetic localization, but observations supporting the occurrence of two closely linked genes regulating these different activities are available. In conclusion, 4-5 genes determining the capacity for several reactions, being a part of the genetic regulation of the cytochrome P-450 system in Drosophila melanogaster were indicated.     

Linkage of loci affecting a murine liver protein and arylsulfatase B to chromosome 13

As-1 is the putative structural locus for murine arylsulfatase B, and Lth-1 determines the presence or absence of a 35 000 dalton acidic liver protein. As-1 and Lth-1 were found to be closely linked using recombinant inbred (RI) strains. Both loci were found to have been cotransferred with the pearl (pe) coat color mutation (chromosome 13) in the B6.C3H pe/pe congenic strain. The linkage relationships between pe, Lth-1, and As-1 were further defined in a backcross. On the basis of the RI data, the congenic strain result, and the backcross data, the following genetic distances were estimated: pe--As-1, 7.1 +/- 4.0 cM; As-1--Lth-1, 2.5 +/- 1.0 cM; and pe--Lth-1, less than 6.9 cM. As-1 and Lth-1 are the first biochemically defined loci to be added to the chromosome 13 linkage map.     

Genetic heterogeneity of plasma lipoproteins in the mouse: control of low density lipoprotein particle sizes by genetic factors

In order to assess the genetic control of sizes and concentrations of mouse plasma low density (LDL) and high density lipoproteins (HDL), we used gel permeation fast protein liquid chromatography (FPLC) and nondenaturing gradient polyacrylamide gel electrophoresis to measure the particle sizes of LDL and HDL. Using chromatography we also quantified LDL-cholesterol and HDL-cholesterol concentrations in plasma and used them as indexes of plasma concentrations of the respective particles among 10 inbred strains (AKR/J, BALB/cByJ, C3H/HeJ, C57BL/6J, C57BL/6ByJ, C57L/J, DBA/1LacJ, 129/J, NZB/BINJ, SWR/J) and three sets of recombinant inbred (RI) strains (AKXL/TyJ, BXH/TyJ, CXB/ByJ) of mice. HDL had a dichotomous distribution among the 10 inbred strains. One group had large HDL particle sizes and high HDL-cholesterol concentrations. Another group had smaller HDL particles and lower HDL-cholesterol concentrations, and HDL sizes and HDL-cholesterol concentrations were significantly correlated. In the RI strains, HDL sizes and HDL-cholesterol cholesterol concentrations clearly segregated with one or another of the progenitor strains, and RI strain distributions showed a strong linkage to the apolipoprotein (apo) A-II gene (Apoa-2). In contrast, LDL-cholesterol concentrations and particle sizes on FPLC did not show dichotomous distributions among the 10 inbred strains. In RI strains, the configuration of the LDL FPLC profiles and LDL-cholesterol concentrations did resemble one or another of the progenitors in the majority of cases, but LDLs of several RI strains resembled neither progenitor strain in profile configuration, and LDL-cholesterol concentrations were both greater and smaller than those of progenitor strains. However, LDL particle diameters (as judged by peaks of LDL-cholesterol profiles) did segregate with progenitors in 29/33 (88%) of RI strains suggesting that a major gene may affect LDL size. In attempting to identify a major LDL-size determining gene, we compared apoB gene restriction fragment length polymorphisms (RFLPs) to the distributions of peak LDL sizes in RI strains. Concordance rates of peak LDL sizes to apoB gene polymorphisms were 18/22 (82%) for the EcoRV RFLP, 5/7 (71%) for HindIII RFLP, and 23/29 (79%) for both (range of P values 0.90-0.95). Thus we could not unequivocally implicate the apoB gene in determining the size of LDL particles. In summary, the genetic control of LDL sizes is more complicated than is the case for HDL; however, the differences in LDL size among these strains of mice may be controlled by a major, as yet unidentified, gene.     

Genotyping new BXD recombinant inbred mouse strains and comparison of BXD and consensus maps

Nine additional BXD recombinant inbred (RI) strains have been developed from the F₂ cross of C57BL/6J and DBA/2J mouse strains. A tenth line stopped breeding in the F₁₂ generation. F₂₀ generation breeding pairs from the nine surviving strains and an F₁₂ pair from the extinct line were genotyped at 319 genetic markers (primarily microsatellites) spanning most of the genome. Where typing data were lacking, the established set of 26 BXD strains also were genotyped at these same loci. The availability of these additional nine strains enhances the value of the BXD RI set for analysis of complex phenotypic traits. The proportion of loci still segregating at the F₂₀ generation was found to closely approximate expectation, suggesting that selection favoring the retention of heterozygosity is not a strong factor. However, the number of crossovers between adjacent markers was frequently less than predicted from consensus map distances. A significant deficiency of recombinants was observed on Chrs 3, 4, 14, and X. On Chr 14, the estimated cumulative BXD map distance between the most proximal and distal markers was only 30.2 cM, compared with a distance of 60.0 cM in the consensus map. On the X Chr, the estimated and predicted cumulative distances were 38.8 and 69.5 cM, respectively. Over all chromosomes, the BXD RI map is 14.5% shorter than predicted from the consensus map. It is suggested that distances in some of the consensus maps are inflated. Alternatively, recombinant genotypes could be selected against during inbreeding owing to allelic interactions affecting fitness. The latter interpretation implies that relatively strong intrachromosomal epistasis is common. Received: 2 October 1998 / Accepted: 15 December 1998     

Genetic identification of endogenous polytropic proviruses by using recombinant inbred mice.

Forty-seven endogenous polytropic murine viruses (Pmv) were identified by examination of proviral-cellular DNA junction fragment segregation in recombinant inbred (RI) mice. Most Pmv loci were found in more than one of the seven RI progenitor strains analyzed, but only four were present in all strains. Chromosomal assignments for 41 Pmv loci were determined by comparing their RI strain distribution patterns with those of known genetic markers. Pmv loci were found dispersed throughout the genome, with chromosomes 1, 3, 4, 5, 7, 11, 12, 15, and 16 each carrying three or more proviruses. Linkage analysis in the AKXD RI set suggested that the gene encoding mink cell focus-forming virus resistance (Rcmfr) of DBA/2J mice is probably not a Pmv provirus. It was also deduced that no single, AKR/J-specific Pmv provirus is required as an env gene donor for thymomagenic mink cell focus-forming viruses. In addition, a Pmv provirus was very closely associated with the albino mutation on chromosome 7.     

The Nxsm Recombinant Inbred Strains of Mice: Genetic Profile for 58 Loci Including the Mtv Proviral Loci

We report the construction of 17 recombinant inbred (RI) strains of mice derived from the progenitor strains NZB/BINRe and SM/J and the typing of this RI strain set, designated NXSM, for 58 loci distributed on 16 autosomes and the X chromosome. Two backcrosses involving NZB/BINJ and SM/J were constructed to confirm chromosomal assignments and determine gene orders suggested from NXSM RI strain data. From these results we recommend that chromosomal assignments and gene orders suggested from analyses of RI strain sets be confirmed using data obtained by other means. We also typed NZB/BINJ and SM/J for mammary tumor proviral (Mtv) loci. Both strains share three previously described Mtv loci: Mtv-7, Mtv-14 and Mtv-17. In addition, NZB/BINJ contains the previously described Mtv-3 and Mtv-9 loci and two new Mtv proviral loci: Mtv-27 located on chromosome (Chr) 1 and Mtv-28 located on the X chromosome. SM/J contains the previously described loci Mtv-6 and Mtv-8. Four LTR, mink cell focus-forming murine leukemia viral loci were identified and mapped: Ltrm-1 on Chr 12, Ltrm-2 on Chr 16, Ltrm-3 on Chr 5, and Ltrm-4 on Chr 13. The Tgn locus was positioned proximal to the Ly-6 locus on Chr 15.     

Establishment of a molecular genetic map of distal mouse chromosome 1: further definition of a conserved linkage group syntenic with human chromosome 1q

A linkage map of distal mouse chromosome 1 was constructed by restriction fragment length polymorphism analysis of DNAs from seven sets of recombinant inbred (RI) strains. The data obtained with seven probes on Southern hybridization combined with data from previous studies suggest the gene order Cfh, Pep-3/Ren-1,2, Ly-5, Lamb-2, At-3, Apoa-2/Ly-17,Spna-1. These results confirm and extend analyses of a large linkage group which includes genes present on a 20-30 cM span of mouse chromosome 1 and those localized to human chromosome 1q21-32. Moreover, the data indicate similar relative positions of human and mouse complement receptor-related genes REN, CD45, LAMB2, AT3, APOA2, and SPTA. These results suggest that mouse gene analyses may help in detailed mapping of human genes within such a syntenic group.     

Genetic analysis of the distribution of corticosterone-containing cells in mouse adrenal cortex

Strains A/J and C57BL/6J (B6) differ in susceptibility to many neoplasms and infectious agents, with B6 mice generally being more resistant. Glucocorticoids protect against some of these pathologies. We examined the distribution of adrenocortical corticosterone (CS), the major endogenous glucocorticoid in mice, in these strains, using anti-CS serum. A distinct strain difference was found. B6 adrenals exhibited abundant CS-positive cells in cord-like arrays while A/J adrenals contained fewer, randomly arranged CS-positive cells. To quantify these results, each adrenal cortex was divided into eight sectors and each sector was classified as to phenotype. Ninety-three percent of the sectors of B6 cortices exhibited the cord-like pattern, whereas only 15% of the sectors of A/J cortices exhibited this pattern. These differences are consistent with a hypothesis that A/J mice are relatively deficient in the prophylactic activities of endogenous glucocorticoids. Adrenal glands from (C57BL/6J x A/J)F1 hybrid mice had approximately equal proportions of areas exhibiting each phenotype, indicating codominant alleles for this trait. We propose the name Cor for this gene. Thirty AXB and BXA recombinant inbred (RI) lines of mice derived from A/J and B6 progenitors were examined for CS immunostaining. Twenty-eight of them had either predominantly A/J-like or predominantly B6-like phenotypes. These RI data support either of two hypotheses. Hypothesis 1 emphasizes the nearly complete concordance of the RI lines with progenitor phenotypes and proposes that a single Cor gene regulates the distribution of CS-positive cells. Using this model, the strain distribution among RI lines implies linkage of Cor to a region on chromosome 6, 27-37 cM from the centromere. Hypothesis 2, which gives greater weight to the two RI lines with intermediate numbers of CS-positive cells, postulates an epistatic interaction between two Cor loci.     

New quantitative trait loci for the genetic variance in circadian period of locomotor activity between inbred strains of mice

Provisional quantitative trait loci (QTL) for circadian locomotor period and wheel-running period have been identified in recombinant inbred (RI) mouse strains. To confirm those QTL and identify new ones, the genetic component of variance of the circadian period was partitioned among an F2 intercross of RI mouse strains (BXD19 and CXB07). First, a genomic survey using 108 SSLP markers with an average spacing of 15 cM was carried out in a population of 259 (BXD19 x CXB07)F2 animals. The genome-wide survey identified two significant QTL for period of locomotor activity measured by infrared photobeam crossings on mouse chromosomes 1 (lod score 5.66) and 14 (lod score 4.33). The QTL on distal chromosome 1 confirmed a previous report based on congenic B6.D2-Mtv7a/Ty mice. Lod scores greater than 2.0 were found on chromosomes 1, 2, 6, 12, 13, and 14. In a targeted extension study, additional genotyping was performed on these chromosomes in the full sample of 341 F2 progeny. The 6 chromosome-wide surveys identified 3 additional QTL on mouse chromosomes 6, 12, and 13. The QTL on chromosome 12 overlaps with circadian period QTL identified in several prior studies. For wheel-running period, the chromosome-wide surveys identified QTL on chromosomes 2 and 13 and one highly suggestive QTL on proximal chromosome 1. The results are compared to other published studies of QTL of circadian period.     

Linkage and mapping analyses of the densonucleosis non-susceptible gene nsd-Z in the silkworm Bombyx mori using SSR markers.

In the silkworm Bombyx mori, non-susceptibility to the Zhenjiang (China) strain of the densonucleosis virus (DNV-Z) is controlled by the recessive gene nsd-Z (non-susceptible to DNV-Z), which is located on chromosome 15. Owing to a lack of crossing over in females, reciprocal backcrossed F1 (BC1) progeny were used for linkage analysis and mapping of the nsd-Z gene using silkworm strains Js and L10, which are classified as being highly susceptible and non-susceptible to DNV-Z, respectively. BC1 larvae were inoculated with the DNV-Z virus at the first instar, and DNA was extracted from the individual surviving pupae and analyzed for simple sequence repeat (SSR) markers. The nsd-Z gene was found to be linked to 7 SSR markers, as all the surviving larvae in the BC1female (F1female x L10male) showed the homozygous profile of strain L10, and the sick larvae in the BC1female (F1female x L10male) showed the heterozygous profile of Js x L10 F1 hybrids. Using a reciprocal BC1male (L101female x F1male) cross, we constructed a linkage map of 80.6 cM, with nsd-Z mapped at 30 cM and the closest SSR marker at a distance of 4.4 cM.     

Two-Locus Linkage Analysis Using Recombinant Inbred Strains and Bayes'' Theorem

Recombinant inbred (RI) strains are useful in linkage analysis and gene mapping. The currently available statistical tests of linkage using data derived from the study of RI strains, including a previous Bayesian analysis, have not been stringent enough guides for conclusions about linkage. In this paper, the probability of linkage was estimated using Bayes' theorem. Tables are presented that give the probability of linkage in sets of up to 30 RI strains and the critical values of i (the number of recombinants) in sets of up to 100 RI strains. Several means of increasing the power of RI strains in linkage analysis are discussed.