Domestication of Pea (Pisum sativum L.): The Case of the Abyssinian Pea.

Phylogenetic relationships of the Abyssinian pea (Pisum sativum ssp. abyssinicum) to other subspecies and species in the genus were investigated to test between different hypotheses regarding its origin and domestication. An extensive sample of the Pisum sativum ssp. sativum germplasm was investigated, including groups a-1, a-2, b, c, and d as identified by Kwon et al. (2012). A broad sample of P. fulvum but relatively few P. s. ssp. elatius accessions were analyzed. Partial sequences of 18 genes were compared and these results combined with comparisons of additional genes done by others and available in the literature. In total, 54 genes or gene fragment sequences were involved in the study. The observed affinities between alleles in P. ssp. sativum, P. s. ssp. abyssinicum, P. s. ssp. elatius, and P. fulvum clearly demonstrated a close relationship among the three P. sativum subspecies and rejected the hypothesis that the Abyssinian pea was formed by hybridization between one of the P. sativum subspecies and P. fulvum. If hybridization were involved in the generation of the Abyssinian pea, it must have been between P. s. ssp. sativum and P. s. ssp. elatius, although the Abyssinian pea possesses a considerable number of highly unique alleles, implying that the actual P. s. ssp. elatius germplasm involved in such a hybridization has yet to be tested or that the hybridization occurred much longer ago than the postulated 4000 years bp. Analysis of the P. s. ssp. abyssinicum alleles in genomic regions thought to contain genes critical for domestication indicated that the indehiscent pod trait was independently developed in the Abyssinian pea, whereas the loss of seed dormancy was either derived from P. s. ssp. sativum or at least partially developed before the P. s. ssp. abyssinicum lineage diverged from that leading to P. s. ssp. sativum.

Are Mendel's Data Reliable? The Perspective of a Pea Geneticist.

Mendel's data exhibit remarkable agreement to the ratios he predicted. In this article, alternative explanations for this close agreement (that inheritance in pea does not conform to the standard statistical model, that data were omitted, that ambiguous data were categorized to better match predicted ratios, and that some data were deliberately falsified) are tested using approaches that are designed to distinguish between these alternatives. The possibility that garden pea (Pisum sativum L.) naturally produces segregation ratios more closely matching Mendelian expectations than predicted by statistical models is rejected. Instead the opposite is found to be the case, making Mendel's results even more remarkable. Considerable evidence is introduced that Mendel omitted some of his experimental results, but this alternative cannot adequately explain the low average deviation from expectations that is characteristic of the segregation data he presented. An underlying bias in Mendel's data favoring the predicted ratio is present, but my analysis could not clearly determine whether the bias was caused by misclassifying ambiguous phenotypes or deliberate falsification of the results. A number of Mendel's statements are argued to be unrealistic in terms of practical pea genetics, suggesting that his text does not represent a strictly accurate description of his experimental methods. Mendel's article is probably best regarded as his attempt to present his model in a simple and convincing format with a minimum of additional details that might obscure his message.

Genetic analysis of an interspecific cross in ornamental Viburnum (Viburnum).

A genetic analysis was performed on a population derived from crosses between Viburnum lantana and Viburnum carlesii. Linkage maps were developed for each species using AFLP, random amplified polymorphic DNA (RAPD), and sequence-tagged site markers and a half-sib approach that took advantage of both the polymorphism between the species and the heterozygosity within each parent. The map for V. lantana consisted of 153 DNA markers and spanned approximately 750 cM, whereas that for V. carlesii contained 133 markers and covered 700 cM. These maps were used to determine the location of several major genes influencing leaf spot resistance, Verticillium wilt resistance, bud color, and flower scent. Both species contained moderate levels of heterozygosity. Flow cytometric analysis revealed that the genome of V. lantana was 40% larger than that of V. carlesii, and this difference was paralleled by a proportionally greater number of intercross markers (markers segregating 3:1) from V. lantana than from V. carlesii. In addition, V. lantana (n = 9) displayed a 10th linkage group for which no homolog in V. carlesii (n = 9) could be found and which contained only markers present in the former species and absent in the latter. These results suggest that Viburnum could be an interesting genetic model for Caprifoliaceae sensu lato.

Genetic changes accompanying the domestication of Pisum sativum: is there a common genetic basis to the 'domestication syndrome' for legumes?

BACKGROUND AND AIMS: The changes that occur during the domestication of crops such as maize and common bean appear to be controlled by relatively few genes. This study investigates the genetic basis of domestication in pea (Pisum sativum) and compares the genes involved with those determined to be important in common bean domestication. METHODS: Quantitative trait loci and classical genetic analysis are used to investigate and identify the genes modified at three stages of the domestication process. Five recombinant inbred populations involving crosses between different lines representing different stages are examined. KEY RESULTS: A minimum of 15 known genes, in addition to a relatively few major quantitative trait loci, are identified as being critical to the domestication process. These genes control traits such as pod dehiscence, seed dormancy, seed size and other seed quality characters, stem height, root mass, and harvest index. Several of the genes have pleiotropic effects that in species possessing a more rudimentary genetic characterization might have been interpreted as clusters of genes. Very little evidence for gene clustering was found in pea. When compared with common bean, pea has used a different set of genes to produce the same or similar phenotypic changes. CONCLUSIONS: Similar to results for common bean, relatively few genes appear to have been modified during the domestication of pea. However, the genes involved are different, and there does not appear to be a common genetic basis to 'domestication syndrome' in the Fabaceae.

Genetic analysis of pod dehiscence in pea (Pisum sativum L.).

The inheritance of the dehiscent pod character was investigated in two recombinant inbred populations using a simplified correlation analysis. The approach identified three regions on the pea genome that affect the expression of pod dehiscence. The region on linkage group III corresponded to the expected position of Dpo, a gene known to influence pod dehiscence. A locus on linkage group V appeared to have a slightly smaller effect on expression of the phenotype. The third region was observed only in one cross, had a greater effect than Dpo, and was postulated to be yellow pod allele at the Gp locus

DISTRIBUTION AND EVOLUTION OF A GLUCOSEPHOSPHATE ISOMERASE DUPLICATION IN THE LEGUMINOSAE.

In the common bean, Phaseolus vulgaris, two loci encode cytosolic glucosephosphate isomerase (GPI) subunits, whereas in the garden pea, Pisum sativum, only one locus is expressed. As a working model, we proposed that this change in isozyme number was produced by a gene-duplication event in the lineage leading to Phaseolus after divergence from that leading to Pisum. This model was tested by analyzing the GPI phenotypes in 119 legume genera, representing all three subfamilies and 23 of the 30 tribes of the Papilionoideae. The duplication was detected in 13 of the 20 papilionoid tribes surveyed, including several members of the putatively primitive tribe Sophoreae. Thus, the duplication appears to be an ancient event, a finding incompatible with the initial hypothesis. Instead, gene silencing is postulated to account for the absence of the duplicated phenotype in many tribes, including such advanced groups as Vicieae, Trifolieae, and Cicereae. Furthermore, silencing has occurred numerous times at lower taxonomic levels, including the subtribe Phaseolinae (Phaseoleae), a monophyletic group in which ten genera were found to have duplicated phenotypes and only one (Strophostyles) appeared to have an unduplicated phenotype. Analysis of GPI phenotypes also revealed numerous cases of partial silencing of duplicate loci as well as nearly equal expression of both loci in many, taxonomically widely scattered species. If our revised hypothesis is correct, this latter result implies that most of the subtribes had formed before significant divergence between the GPI isozymes occurred and, thus, that the radiation of the Papilionoideae was rapid relative to the rate of gene silencing.