Establishment of a 100-seed weight quantitative trait locus-allele matrix of the germplasm population for optimal recombination design in soybean breeding programmes.

A representative sample comprising 366 accessions from the Chinese soybean landrace population (CSLRP) was tested under four growth environments for determination of the whole-genome quantitative trait loci (QTLs) system of the 100-seed weight trait (ranging from 4.59g to 40.35g) through genome-wide association study (GWAS). A total of 116 769 single nucleotide polymorphisms (SNPs) were identified and organized into 29 121 SNP linkage disequilibrium blocks (SNPLDBs) to fit the property of multiple alleles/haplotypes per locus in germplasm. An innovative two-stage GWAS was conducted using a single locus model for shrinking the marker number followed by a multiple loci model utilizing a stepwise regression for the whole-genome QTL identification. In total, 98.45% of the phenotypic variance (PV) was accounted for by four large-contribution major QTLs (36.33%), 51 small-contribution major QTLs (43.24%), and a number of unmapped minor QTLs (18.88%), with the QTL×environment variance representing only 1.01% of the PV. The allele numbers of each QTL ranged from two to 10. A total of 263 alleles along with the respective allele effects were estimated and organized into a 263×366 matrix, giving the compact genetic constitution of the CSLRP. Differentiations among the ecoregion matrices were found. No landrace had alleles which were all positive or all negative, indicating a hidden potential for recombination. The optimal crosses within and among ecoregions were predicted, and showed great transgressive potential. From the QTL system, 39 candidate genes were annotated, of which 26 were involved with the gene ontology categories of biological process, cellular component, and molecular function, indicating that diverse genes are involved in directing the 100-seed weight.

Molecular mapping of 36 soybean male-sterile, female-sterile mutants.

Mutability of the w(4) flower color locus in soybean [Glycine max (L.) Merr.] is conditioned by an unstable allele designated w(4)-m. Germinal revertants, purple-flower plants, recovered among self-pollinated progeny of mutable flower plants were associated with the generation of necrotic root, chlorophyll-deficiency, and sterility mutations. Thirty-seven male-sterile, female-sterile mutant lines were generated from 37 independent reversion events at the w(4)-m locus. The first germinal revertant study had one male-sterile, female-sterile mutant (st8, T352), located on Molecular Linkage Group (MLG) J. The second study had 36 germinal-revertant derived sterility mutants descended from four mutable categories of w(4)-m. The mutable categories were designated; (1) low frequency of early excisions, (2) low frequency of late excisions, (3) high frequency of early excisions, and (4) high frequency of late excisions. The objectives of the present study were to; (1) molecularly map the 36 male-sterile, female-sterile mutants, and to (2) compare map locations of these mutants with T352 (st8), identified from the first germinal revertant study. Thirty-three of 36 male-sterile, female-sterile mutations were derived from germinal reversions that were classified in the late excision categories. Thirty-five male-sterile mutants mapped to the st8 region on MLG J. The only exception mapped to MLG G. Most likely mutants were generated through insertion of a putative transposon that was excised from the w(4) locus. The location of 36 of 37 mutations to a single chromosomal region suggests preference for sequence-dependent insertion.

Duplicate chlorophyll-deficient loci in soybean.

Three lethal-yellow mutants have been identified in soybean (Glycine max (L.) Merr.), and assigned genetic type collection numbers T218H, T225H, and T362H. Previous genetic evaluation of T362H indicated allelism with T218H and T225H and duplicate-factor inheritance. Our objectives were to confirm the inheritance and allelism of T218H and T225H and to molecularly map the locus and (or) loci conditioning the lethal-yellow phenotype. The inheritance of T218H and T225H was 3 green : 1 lethal yellow in their original parental source germplasm of Glycine max 'Illini' and Glycine max 'Lincoln', respectively. In crosses to unrelated germplasm, a 15 green : 1 lethal yellow was observed. Allelism tests indicated that T218H and T225H were allelic. The molecular mapping population was Glycine max 'Minsoy' x T225H and simple sequence repeat (SSR) markers were used. The first locus, designated y18-1, was located on soybean molecular linkage group B2, between SSR markers Satt474 and Satt534, and linked to each by 4.4 and 13.4 cM, respectively. The second locus, designated y18-2, was located on soybean molecular linkage group D2, between SSR markers Satt543 and Sat-001, and linked to each by 2.2 and 4.4 cM, respectively.

Molecular mapping of four ovule lethal mutants in soybean.

We report genetic mapping of four soybean ovule lethal mutants, PS-1, PS-2, PS-3, and PS-4, which had been identified as female partial-sterile mutants from a gene-tagging study. The four mutants had been classified into two mutation classes: (1) PS-1-sporophytic mutation affects sporophytically expressed genes; and (2) PS-2, PS-3, and PS-4 mutants-female gametophyte-specific mutations affect gametophytically expressed genes and are transmitted through the male, but not the female gametes. Molecular mapping demonstrated that these four mutant genes and previously reported female-partial sterile gene, Fsp1, are located independently on soybean molecular linkage groups (MLG-) using SSR markers. PS-1, designated as Fsp2 and Genetic Type Collection number T364, is located between SSR markers Satt170 and Satt363 on MLG-C2 and linked by 13.9 cM and 12.1 cM, respectively. PS-2, designated as Fsp3 and Genetic Type Collection number T365H, is located between SSR markers Satt538 and Satt429 on MLG-A2 and linked by 13.3 cM and 25.4 cM, respectively. PS-3, designated as Fsp4 and Genetic Type Collection number T366H, is located on the terminus of MLG-F and linked to Sat 152 by 13.1 cM. PS-4, designated as Fsp5 and Genetic Type Collection number T367H, is located between SSR markers Satt324 and Satt138 on MLG-G and linked by 19.6 cM and 7.5 cM, respectively. SSR markers adjacent to Fsp3, Fsp4, and Fsp5 were distorted from a 1:2:1 ratio and fit a 1:1 ratio. The segregation distortions of SSR markers adjacent to Fsp3, Fsp4, and Fsp5 are in support of male, but not female transmission of the Fsp3, Fsp4, and Fsp5 gametes.

Molecular mapping of the male-sterile, female-sterile mutant gene (st8) in soybean.

Soybean male-sterile, female-sterile mutant genes have been identified by genetic and cytological studies. The St8 gene has been identified as an asynaptic mutation resulting in male and female sterility. This mutant gene was derived from a gene-tagging study using the soybean w4-mutable line. In this report we identified the genetic map position of st8 via restriction fragment length polymorphism (RFLP) and simple sequence repeat (SSR) markers. The St8 gene mutation was located between RFLP marker E107 and SSR markers Satt132, Sct_065, and Satt414 on molecular linkage group J and linked to each by 7.8 cM and 3.4 cM, respectively.

360-degree assessment in a multidisciplinary team setting.

OBJECTIVES: To use the 360-degree assessment in the multidisciplinary setting of a rheumatology department and to evaluate its impact, recognizing that this process will become part of the revalidation process of NHS professionals in the future. METHODS: Seventeen team members completed an anonymous questionnaire to give confidential opinions about the clinical, humanistic and other skills of their colleagues. Results and comments were collated and given as feedback to each individual. Before feedback, participants were asked to predict their perceived strengths and weaknesses. After feedback they evaluated the process. RESULTS: A profile of abilities was established for each team member and discussed privately with the clinical director. Often team members had good insight into their perceived strengths and weaknesses. Some participants were hurt by negative comments made about them even if this was balanced by positive comments. There were mixed views on the relevance and usefulness of the process, and whether or not it should be repeated. Some team members found the process threatening. CONCLUSION: The 360-degree assessment can be used in a multidisciplinary setting, the questions being the same for all individuals. It is a very powerful tool that must be handled carefully so that it does not cause more harm than good.

Genetic identification of a female partial-sterile mutant in soybean.

We report here the genetic identification of a female partial-sterile mutant derived from soybean mutant L67-3483. L67-3483, which originated from the cultivar Clark after X-ray irradiation, is male and female fertile. All F1 plants in reciprocal pollinations of L67-3483 with 'Clark', 'Minsoy', or 'BSR 101' were female partial sterile. Partial sterility is expressed in the heterozygous condition at a single locus and upon self-pollination this locus exhibits a 1:1 segregation pattern. This locus is located on the terminus of the soybean molecular linkage group D1b+W, between simple sequence repeat (SSR) markers Satt157 and Satt266, and is linked to each by 5.3 and 1.2 cM, respectively. This gene is transmitted through both female and male gametes and there was no segregation distortion of SSR markers linked to this gene. We concluded that this female partial-sterile gene is a new mutation class, and differs from the previously reported mutation classes in soybean, i.e., sporophytic mutation, gametophytic female-specific mutation, and general gametophytic mutation. Restriction of recombination around the mutant gene suggested that this gene is located near or within (a) small inversion(s) or adjacent to (a) chromosomal deletion(s).

Oxalate content of soybean seeds (Glycine max: Leguminosae), soyfoods, and other edible legumes.

Consumption of soybeans and food products made from them is increasing because of their desirable nutritional value. However, the oxalate content of seeds from 11 cultivars of soybean showed relatively high levels of total oxalate from 0.67 to 3.5 g/100 g of dry weight. Oxalate primarily was found as calcium oxalate crystals. Thirteen tested commercial soyfoods contained between 16 and 638 mg of total oxalate per serving. These values compare to those of three other legume foods, peanut butter, refried beans, and lentils, which contained 197, 193, and 100 mg of total oxalate per serving, respectively. After oxalate has been absorbed from the diet, it cannot be metabolized and is excreted by the kidney into urine, where it binds to calcium forming an insoluble salt that may precipitate to form kidney stones. The amounts of total oxalate in soybean seeds, soy foods, and other common legume foods exceed current recommendations for oxalate consumption by individuals who have a history of calcium oxalate kidney/urinary stones. This study serves as the basis to find soybean cultivars lower in oxalate, which will have lower risk for kidney stone formation after human consumption.

Independent spontaneous mitochondrial malate dehydrogenase null mutants in soybean are the result of deletions.

The mitochondrial malate dehydrogenase-1 (Mdh1) gene of soybean [Glycine max (L.) Merr.] spontaneously mutates to a null phenotype at a relatively high rate. To determine the molecular basis for the instability of the Mdh1 gene, the gene was cloned and sequenced. The null phenotype correlated with the deletion of specific genomic restriction fragments that encode the Mdh1 gene. The composition of the Mdh1 gene and its environs were compared with those of the more stable MDH2 gene. Several possible causes of the observed instability were found, including duplications, repeats, and two regions with similarity to a soybean catalase. The most likely cause of instability, however, appeared to be a 1233 bp region with 58.9% identity to the Cyclops retrotransposons. Translation of a 714 bp segment of this region produced a peptide composed of 238 amino acid residues that showed 35-40% identity and 55-60% similarity to several putative Cyclops gag-pol proteins (group-specific antigen polyprotein). This short peptide also contained a segment that corresponded to the protease active site of the gag-pol protein. Thus in an appropriate genetic background, a retrotransposon, whether whole or fractured, could promote genetic rearrangements.

A soybean plastid-targeted NADH-malate dehydrogenase: cloning and expression analyses.

A typical soybean (Glycine max) plant assimilates nitrogen rapidly both in active root nodules and in developing seeds and pods. Oxaloacetate and 2-ketoglutarate are major acceptors of ammonia during rapid nitrogen assimilation. Oxaloacetate can be derived from the tricarboxylic acid (TCA) cycle, and it also can be synthesized from phosphoenolpyruvate and carbon dioxide by phosphoenolpyruvate carboxylase. An active malate dehydrogenase is required to facilitate carbon flow from phosphoenolpyruvate to oxaloacetate. We report the cloning and sequence analyses of a complete and novel malate dehydrogenase gene in soybean. The derived amino acid sequence was highly similar to the nodule-enhanced malate dehydrogenases from Medicago sativa and Pisum sativum in terms of the transit peptide and the mature subunit (i.e., the functional enzyme). Furthermore, the mature subunit exhibited a very high homology to the plastid-localized NAD-dependent malate dehydrogenase from Arabidopsis thaliana, which has a completely different transit peptide. In addition, the soybean nodule-enhanced malate dehydrogenase was abundant in both immature soybean seeds and pods. Only trace amounts of the enzyme were found in leaves and nonnodulated roots. In vitro synthesized labeled precursor protein was imported into the stroma of spinach chloroplasts and processed to the mature subunit, which has a molecular mass of ∼34 kDa. We propose that this new malate dehydrogenase facilitates rapid nitrogen assimilation both in soybean root nodules and in developing soybean seeds, which are rich in protein. In addition, the complete coding region of a geranylgeranyl hydrogenase gene, which is essential for chlorophyll synthesis, was found immediately upstream from the new malate dehydrogenase gene.

Genetics and cytology of a genic male-sterile, female-sterile mutant from a transposon-containing soybean population.

A male-sterile, female-sterile soybean mutant (w4-m sterile) was identified among progeny of germinal revertants of a gene-tagging study. Our objectives were to determine the genetics (inheritance, allelism, and linkage) and the cytology (microsporogenesis and microgametogenesis) of the w4-m sterile. The mutant was inherited as a single recessive nuclear gene and was nonallelic to known male-sterile, female-sterile mutants st2 st2, st3 st3, st4 st4, st5 st5, and st6 st6 st7 st7. No linkage was detected between the w4-m sterile and the w4w4, y10 y10, y11 y11, y20 y20, fr1 fr1, and fr2 fr2 mutants. Homologous chromosome pairing was complete in fertile plants. Chromosome pairing, as observed in squash preparation, was almost completely absent in sterile plants. Developmentally microsporogenesis proceeded normally in both the fertile and the w4-m sterile through the early microspore stage. Then the tapetal cells of the w4-m sterile surrounding the young microspores developed different-size vacuoles. These tapetal cells became smaller in size and separated from each other. Some of the microspores of the w4-m sterile also became more vacuolate prematurely and sometimes they collapsed, usually by the late microspore stage. In the w4-m sterile the microspore walls remained thinner and structurally different from the microspore walls of fertile plants. No pollen was formed in the mutant plants, even though some of the male cells reached the pollen stage, although without normal filling. The w4-m sterile was designated st8st8 and assigned Soybean Genetic Type Collection number T352.

Genetic analyses of two independent chlorophyll-deficient mutants identified among the progeny of a single chimeric foliage soybean plant.

Chimeric (variegated) foliage plants are frequently observed in many species. In soybean [Glycine max(L.) Merr.], progeny of chimeric plants are a source of nuclear and cytoplasmically inherited mutants. Self-pollinated progeny of a single chimeric plant derived from tissue culture of PI 427099 (Jilin 3) included plants with green foliage, chimeric foliage, yellow foliage (viable), and yellow foliage (lethal). Our objectives were to determine (1) inheritance, linkage, and allelism of the lethal-yellow mutant with known chlorophyll-deficient mutants; (2) inheritance, linkage, and allelism of the viable-yellow mutant with known chlorophyll-deficient mutants; (3) allelism of the lethal-yellow mutant with the viable-yellow mutant; and (4) male and female gamete transmission of the viable-yellow mutant trait. The viable-yellow mutant was allelic to T323, y20 y20 (Ames 2) Mdh1-n Mdh1-n (Ames 2) and was assigned genetic type collection number T361 and gene symbol y20 y20 (Ames 24) Mdh1-n Mdh1-n (Ames 22). The lethal-yellow mutant was allelic to T225H (Y18 y18) and was assigned genetic type collection number T362H and gene symbol Y18 y18 (Ames 2). T225H became Y18 y18 (Ames 1). The two chlorophyll-deficient mutants were not linked to each other. There was no significant difference in F(1) male or female gamete transmission of the viable-yellow mutant. However, many cross-combinations gave significant deviations from the expected 3 green plants:1 viable-yellow plant in the F(2) generation. The allelism of these two chlorophyll-deficient mutants with mutants T225H and T323, derived from putative transposable element systems, is intriguing. An explanation of this phenomenon awaits molecular experimentation.

Behçet's syndrome: a multidisciplinary approach to clinical care.

Behçet's syndrome is a multisystem disorder characterized by recurrent orogenital ulceration and an occlusive vasculitis. Histologically, there is a combination of a perivascular lymphocytic infiltration with endothelial cell damage coupled with a pro-thrombotic tendency. We present a multidisciplinary approach to the management of Behçet's syndrome, and compare our findings with other published studies. Over a nine-year period, 50 patients with Behçet's syndrome were followed in a multidisciplinary combined clinic. Patients were assessed by an ophthalmologist, a rheumatologist and a specialist in oral medicine. Data on disease activity and damage were collected using a standardized proforma for each specialty. Mean age of onset was 30 years; 56% were male. Recurrent oral ulceration was the commonest manifestation and the presenting feature in 76%. The commonest second systems involved were genital mucosae and eyes. We found a larger proportion of patients with ophthalmic (80%) and central nervous system (14%) manifestations compared with many other studies. There was an association between central nervous system and thrombotic events (p<0.001). Our multidisciplinary approach allowed us to keep each system involved in Behçet's syndrome under careful review. The development of recurrent sight-threatening eye disease was unpredictable and occurred despite aggressive immunosuppression.

Analysis and mapping of gene families encoding beta-1,3-glucanases of soybean.

Oligonucleotide primers designed for conserved sequences from coding regions of beta-1,3-glucanase genes from different species were used to amplify related sequences from soybean [Glycine max (L.) Merr.]. Sequencing and cross-hybridization of amplification products indicated that at least 12 classes of beta-1,3-glucanase genes exist in the soybean. Members of classes mapped to 34 loci on five different linkage groups using an F(2) population of 56 individuals. beta-1,3-Glucanase genes are clustered onto regions of five linkage groups. Data suggest that more closely related genes are clustered together on one linkage group or on duplicated regions of linkage groups. Northern blot analyses performed on total RNA from root, stem, leaf, pod, flower bud, and hypocotyl using DNA probes for the different classes of beta-1,3-glucanase genes revealed that the mRNA levels of all classes were low in young leaves. SGlu2, SGlu4, SGlu7, and SGlu12 mRNA were highly accumulated in young roots and hypocotyls. SGlu7 mRNA also accumulated in pods and flower buds.

Instability at the k2 Mdh1-n y20 chromosomal region in soybean.

Ten mutants have been reported at the k2 (tan saddle seed coat) Mdh1-n (mitochondrial malate dehydrogenase 1 null) y20 (yellow foliage) chromosomal region in soybean [Glycine max (L.) Merr.]. The precise genetic mechanism(s) responsible for generating these mutants is (are) not known. The objective of this study was to determine whether chromosomal instability exists at this region. We introduced the w4-m and Y18-m mutable systems into the three independent sources of tan saddle seed coat mutants, T239 (k2), T261 (k2 Mdh1-n), and L67-3483 (k2). A total of 12 bright yellow mutants were isolated with tan saddle seed coat, malate dehydrogenase 1 null phenotypes. Of these, 11 were found in 11 F2 mutant families out of a total of 977 derived by crossing T239 (k2), T261 (k2 Mdh1-n), and L67-3483 (k2) with six lines suspected to contain active transposable elements. One was found in the F3 generation derived from the cross A1937 x T239 (k2). Of the 11 F2 mutant families, 10 (out of a total of 381 F2 families) were associated with the T239 (k2) genetic background, and one out of 323 was associated with the T261 (k2 Mdh1-n) genetic background. But no mutation events were found among the 273 families with the L67-3483 (k2) genetic background. Allelism and inheritance studies indicated that these 12 bright yellow mutants were new mutants in the k2 Mdh1-n y20 chromosomal region. Thus, on introducing the w4-m and Y18-m mutable systems into T239 (k2) and T261 (k2 Mdh1-n) genetic backgrounds, chromosomal instability was induced in this region. In addition, 21 greenish yellow mutants were identified in the total of 977 F2 families. All 21 greenish yellow mutants were associated with the T239 (k2) genetic background. The mutations for greenish yellow foliage affected foliage color only at the seedling stage. Cosegregation of the tan saddle seed coat character with greenish yellow foliage were observed for these 21 greenish yellow mutants, suggesting that the greenish yellow phenotype may be due to a pleiotropic effect of the k2 allele in T239 or to chromosomal rearrangements at or near the k2 allele in T239. Finally, we believe that the genetic mechanism responsible for this high frequency of instability at the k2 Mdh1-n y20 chromosomal region involves receptor element activities present at this chromosomal region, which may contain complex chromosomal rearrangements in T239 and T261.

Genetic and cytological analyses of three lethal ovule mutants in soybean (Glycine max; Leguminosae).

Soybean partially sterile mutants 2, 3, and 4 (PS-2, PS-3, and PS-4), recovered from a gene-tagging experiment, were studied to clarify their inheritance, linkage, allelism, and reproductive biology. The PS-2, PS-3, and PS-4 mutants were maintained as heterozygotes and upon self-pollination segregated l fertile: l partially-sterile. For inheritance and linkage tests, all three PS mutants were crossed to flower color mutant Harosoy-w4 and to chlorophyll-deficient (CD) mutants CD-1 and CD-5, also recovered from the tagging study. For allelism tests, reciprocal crosses were made among the three partially sterile mutants. Linkage results indicated that the gene for partial sterility in the PS-2, PS-3, and PS-4 mutants was not linked either to the w4 locus or to the genes for chlorophyll deficiency. Studies of pollen development, pollen viability, and pollen-tube germination indicated no difference between normal and partially sterile genotypes. Linkage and allelism tests indicated that the gene in the three partially sterile mutants was not transmitted through the female when they were used as a female parent. A study of megagametogenesis indicated that the ovules from partially sterile plants had normal embryo sac development. Ovule abortion was due to failure of fertilization.

Programmed cell death in the root cortex of soybean root necrosis mutants.

The soybean root necrosis (rn) mutation causes a progressive browning of the root soon after germination that is associated with accumulation of phytoalexins and pathogenesis-related proteins and an increased tolerance to root-borne infection by the fungal pathogen, Phytophthora sojae. Grafting and decapitation experiments indicate that the rn phenotype is root-autonomous at the macroscopic level. However, the onset and severity of browning was modulated in intact plants by exposure to light, as was the extent of lateral root formation, suggesting that both lateral roots and the rn phenotype could be directly or indirectly controlled by similar shoot-derived factors. Browning first occurs in differentiated inner cortical cells adjacent to the stele and is preceded by a wave of autofluorescence that emanates from cortical cells opposite the xylem poles and spreads across the cortex. Before any visible changes in autofluorescence or browning, fragmented DNA was detected by TUNEL (Terminal deoxynucleotidyl transferase-mediated dUTP-digoxigenin nick end labeling) in small clusters of inner cortical cells that subsequently could be distinguished cytologically from neighboring cells throughout rn root development. Inner cortical cells overlying lateral root primordia in either Rn or rn plants also were stained by TUNEL. Features commonly observed in animal cell apoptosis were confirmed by electron microscopy but, surprisingly, cells with a necrotic morphology were detected alongside apoptotic cells in the cortex of rn roots when TUNEL-positive cells were first observed. The two morphologies may represent different stages of a common pathway for programmed cell death (pcd) in plant roots, or two separate pathways of pcd could be involved. The phenotype of rn plants suggests that the Rn gene could either negatively regulate cortical cell death or be required for cortical cell survival. The possibility of a mechanistic link between cortical cell death in rn plants and during lateral root emergence is discussed.

Authoritarianism, inner/other directedness, and sensation seeking in firefighter/paramedics: their relationship with burnout.

INTRODUCTION: Burnout in firefighter/paramedics (FF/EMT-Ps) is widely believed to exist, but few empirical data support its existence, symptomatology, or intervention. Understanding the extent, nature, and cause of burnout is crucial to improving employee morale and performance. STUDY POPULATION: Ninety-one FF/EMT-Ps employed by Salt Lake County Fire Department. HYPOTHESES: Three specific hypotheses were tested: 1) FF/EMT-Ps who score high on burnout will also score high on authoritarianism; 2) FF/EMT-Ps who score high on burnout also will score high on inner-directedness; and 3) FF/EMT-Ps who score high on burnout also will score high on sensation seeking. METHODS: In this descriptive study, FF/EMT-Ps completed four standardized instruments measuring authoritarianism, burnout, inner-directedness versus other-directedness, and sensation seeking. RESULTS: Firefighters who scored high on burnout also scored high on authoritarianism and on the sensation-seeking subscale of boredom. Burnout did not correlate with the overall sensation-seeking scale or with its other subscales (thrill, experience, and disinhibition), or inner-directedness versus other-directedness. CONCLUSION: A focus on control issues needs to be an integral part of programs for decreasing employee burnout among FF/EMT-Ps. Specific components of such programs should include stress management and counseling. In addition, management personnel need to be taught not only to assist direct-service staff, but also to recognize and deal with their own control issues as they affect job performance.

A testcross procedure for selecting exotic strains to improve pure-line cultivars in predominantly self-fertilizing species.

Methods for identifying germplasm carrying alleles with the potential to improve a particular single-cross hybrid have been proposed and discussed in recent years. There is a need for similar methods to be used in breeding crops for which pure-line cultivars, rather than hybrids, are the goal. The objective of this research was to develop a method to identify germplasm lines with the potential to contribute favorable alleles not present in a specified pure line or set of pure lines. Given a set of adapted pure lines (A 1, A 2 ..., A m) to be improved and a set of germplasm lines (P 1 P 2 ..., P f), the procedure consists of producing all f x m possible hybrids and evaluating them along with the parents. The testcross statistic T ij is defined by T ij=γ(F ij-A j)+(1-γ) (F ij-P i), where A j, P i, and F ij represent the performance of thej (th) adapted line, the i (th) germplasm line, and their hybrid, respectively. The statistic [Formula: see text] is the mean value of T ij over all adapted parents A j. If γ=(1/2)(1+d'), where d' = the mean degree of dominance, then T ij measures the potential for alleles from P i to improve A j and [Formula: see text] measures the potential for alleles from P i to improve the set A 1, A 2 ..., A m. Use of data on soybean and peanut hybrids published by other researchers suggests that the value assumed for d' has little effect on the P i chosen. The ability of the T ij and [Formula: see text] statistics to identify germplasm strains carrying rare favorable alleles should be assessed in empirical studies.