Comparative Embryo Sac Morphology at Anthesis of Cultivated and Wild Species of Arachis

Introgression of germplasm from wild to cultivated species ofArachis is severely impeded because abortion processes oftenoccur as a prepeg-, peg-(gynophore), or postpeg-elongation event.A comparative study of embryo sac morphology at anthesis wasundertaken to determine if observable differences were presentthat could possibly explain abortion prior to peg tip swellingfollowing soil penetration. Two wild Arachis species (A. duranensisand A. stenosperma) plus A. hypogaea cultivars NC 6 and Argentinewere studied. Differences in starch grain concentration andcytoplasmic stranding organization were observed between A.hypogaea cultivars and the wild Arachis species. These differencesprobably have a significant impact on energy availability atsyngamy and the subsequent early cell division of the embryo.An improper energy balance could contribute to the onset ofabortion in interspecific hybrids. Modification in egg apparatusorganization among all species was also observed which may accountfor low percentages of seed recovery resulting from interspecifichybridization attempts. Embryo sac morphology, interspecific hybridization, Arachis hypogaea L., Arachis species, light microscopy, scanning electron microscopy, embryo abortion, fertilization incompatibility, peanuts, groundnut     

Comparison of Embryo Development in Wild and Cultivated Arachis Species

Embryo development following selfing was investigated in twowild diploid peanut species, Arachis batizocoi Krap. et Greg.(coll. K 9484) (2n = 20) and A. duranensis Krap. et Greg. nom.nud. (coll. K 7988) (2n = 20), and one cultivated tetraploidspecies, A. hypogaea L. NC-Ac 18000 (2n = 40). Rates of pegelongation and sequences of embryo development for each specieswere compared. Peg elongation rates were similar for the twowild species, but for A. hypogaea it was only one-third to one-halfthat of the diploid species. Embryos in A. hypogaea showed slightlymore rapid cell division than in the wild species. The observedvariation in reproductive development between the wild and cultivatedspecies indicate that different control mechanisms may governdevelopment in the different species and may be at least partiallyresponsible for failure to produce viable interspecific hybridsat various ploidy levels. The observations are also importantfor determining the time at which embryos of different speciesof Arachis will reach the appropriate stage of development forsuccessful culture on an artificial medium during embryo rescueprocedures. Peanut, Arachis hypogaea, wild species, embryo, peg     

Embryo Rescue in Wide Crosses in Arachis. 2. Embryo Development in Cultured Peg Tips of Arachis hypogaea

Embryo rescue techniques in Arachis are potentially importantfor recovering interspecific hybrids which have the propensityto abort. Pegs are commonly produced in interspecific crosses,but either they fail to reach the soil because growth is arrested,or pods are produced but embryo development is never re-initiated.Peg tips, with the ovule and embryo, of A. hypogaea L. cv. ‘NC6’, were used to determine whether peg tips can be usedas nurse tissue for in vitro culture of embryos. Tissues werecollected 1, 2, 3 and 4 d after self-pollination, after whichpeg meristems were removed from half the pegs, and culturedon five media combinations. Continued reproductive developmentwas observed for embryos cultured at all four collection days;however, the highest frequency of growth was observed in 1-d-oldtissues. Evidence is presented that meristematic activity mayrestrict embryo growth in the 2- to 4-d-old embryos and, oncethe sequence of events is initiated to slow embryo growth, itis not easily reversed in vitro. Achievements of embryo growthto multicellular, globular stages (stages 1–1 or 1–2)encourage the development of methods to recover very young embryosthrough tissue-culture techniques. Embryo culture, morphology, interspecific hybridization, Arachis hypogaea, comparative light and scanning electron microscopy, peanuts, groundnuts     

Embryo Rescue in Wide Crosses in Arachis. 1. Culture of Ovules in Peg Tips of Arachis hypogaea

Interspecific hybridization in Arachis is restricted by earlyembryo abortion for many cross-combinations. Rescue of youngembryos in vitro within a week after fertilization is necessaryto recover these embryos before they abort. Peg tips, with theovule and embryo tissues, of A. hypogaea L. cv. ‘NC 6’,were cultured to compare ovule growth, callus production andpeg elongation. Tissues were collected 1, 2, 3 and 4 d afterself-pollination, after which peg meristems were removed fromhalf the pegs and cultured on five media combinations. One-day-oldpegs had significantly (P = 0.01) more ovule growth than oldertissues. Presence of the meristem had a greater inhibition toovule growth for 2- to 4-d pegs than for 1-d-old pegs. Significantlymore callus was produced on 4-d pegs than younger tissues, andkinetin had the greatest stimulatory effect on callus. Elongationof pegs with the meristem attached was observed most often inmedia with high sucrose levels. The observations indicate thatvery young ovules can be grown in vitro, and techniques maybe applicable to rescue of young embryonic tissues of Arachis. Ovule culture, interspecific hybridization, Arachis hypogaea, peanuts     

Molecular analysis of Arachis interspecific hybrids

Incorporation of genetic resistance against several biotic stresses that plague cultivated peanut, Arachis hypogaea (2n=4x=40), is an ideal option to develop disease resistant and ecologically safe peanut varieties. The primary gene pool of peanut contains many diploid wild species (2n=2x=20) of Arachis, which have high levels of disease and insect resistances. However, transfer of resistant genes from these species into A. hypogaea is difficult due to ploidy level differences and genomic incompatibilities. This study was conducted to monitor alien germplasm transmission, using Random Amplified Polymorphic DNA (RAPD) markers, from two diploid wild species, A. cardenasii and A. batizocoi, into A. hypogaea. Triploid interspecific hybrids were produced by crossing two A. hypogaea cultivars (NC 6 and Argentine) with the two species and by colchicine-treating vegetative meristems, fertility was restored at the hexaploid (C_o) level in the four hybrids. Hexaploids were allowed to self-pollinate for four generations, each referred to as a cycle (C₁, C₂, C_3, and C₄). At each cycle, a backcross was made with the respective A. hypogaea cultivar as the maternal parent and only lineages tracing back to a single hexaploid hybrid were used for RAPD analysis. Analysis of mapped, species-specific RAPD markers in BC₁F₁ to BC₁F₃ hybrids indicated that alien germplasm retention decreased every generation of inbreeding, especially in Argentine and in A. batizocoi crosses. A similar trend was also observed for every cycle in BC₁F₂ and BC₁F₃ families, possibly, due to the loss of alien chromosomes following selfing of hexaploids. RAPD marker analysis of 40–chromosome interspecific hybrid derivatives from the four crosses supported previous reports that reciprocal recombination and/or translocations are the predominant mechanisms for exchange of chromosomal segments. No evidence was found for preferential transfer of alien chromosomal regions to specific linkage groups. The implications for developing disease resistant peanut breeding lines are discussed in light of these findings.     

Use of single-primer DNA amplifications in genetic studies of peanut (Arachis hypogaea L.)

A recent approach to detecting genetic polymorphism involves the amplification of genomic DNA using single primers of arbitrary sequence. When separated electrophoretically in agarose gels, the amplification products give banding patterns that can be scored for genetic variation. The objective of this research was to apply these techniques to cultivated peanut (Arachis hypogaea L.) and related wild species to determine whether such an approach would be feasible for the construction of a genetic linkage map in peanut or for systematic studies of the genus. Two peanut cultivars, 25 unadapted germplasm lines of A. hypogaea, the wild allotetraploid progenitor of cultivated peanut (A. monticola), A. glabrata (a tetraploid species from section Rhizomatosae), and 29 diploid wild species of Arachis were evaluated for variability using primers of arbitrary sequence to amplify segments of genomic DNA. No variation in banding pattern was observed among the cultivars and germplasm lines of A. hypogaea, whereas the wild Arachis species were uniquely identified with most primers tested. Bands were scored (+/–) in the wild species and the PAUP computer program for phylogenetic analysis and the HyperRFLP program for genetic distance analysis were used to generate dendrograms showing genetic relationships among the diploid Arachis species evaluated. The two analyses produced nearly identical dendrograms of species relationships. In addition, approximately 100 F₂ progeny from each of two interspecific crosses were evaluated for segregation of banding patterns. Although normal segregation was observed among the F₂ progeny from both crosses, banding patterns were quite complex and undesirable for use in genetic mapping. The dominant behavior of the markers prevented the differentiation of heterozygotes from homozygotes with certainty, limiting the usefulness of arbitrary primer amplification products as markers in the construction of a genetic linkage map in peanut.     

Utilisation of wild relatives in the genetic improvement of Arachis hypogaea L.

Summary Cross-compatibility of species in section Arachis Krap. et Greg. nom. nud., and chromosome pairing and pollen fertility in their interspecific F₁ hybrids were studied to further understand the phylogenetic relationships among these species. Except those with A. batizocoi Krap. et Greg. nom. nud., hybrids between diploid species have near normal bivalent frequency (9.1–9.8) and moderate to high pollen fertility (60–91%). Hybrids between A. batizocoi and other species have low bivalent frequency (5.2–6.9) and very low pollen fertility (3–7%). These results confirm the earlier separation of these species into two groups based on karyomorphology and Mahalanobis D² calculated on arm ratios. These studies also provide a picture of relative affinities between A. batizocoi, the lone member of one cluster, and the other species, and among the rest of the species. They also indicate that the basic chromosome complement in the two groups of species is the same. Chromosome pairing in triploid hybrids, (A. hypogaea L. X diploid wild species), suggests that A. batizocoi is the closest diploid relative of A. hypogaea. It is closer to A. hypogaea subspecies fastigiata Waldron than to A. hypogaea subspecies hypogaea Krap. et. Rig. Other diploid species of the section Arachis are equidistant from A. hypogaea, and have the same genome which has strong homology to one of the genomes of A. hypogaea. Based on the present results, the two tetraploid species, A. monticola Krap. et Rig. and A. hypogaea can be recognised as two forms of the same species. Breeding implications have been discussed in the light of chromosome behaviour observed in hybrids of A. hypogaea X diploid species, and on the presumptions that A. hypogaea has an AABB genomic constitution, and that among the diploid species, the B genome is present in A. batizocoi while the A genome is common to the other diploid species of section Arachis.Submitted as Journal Article No. 328 by the International Crops Research Institute for the Semi-Arid Tropics (ICRISAT)     

Production of peanut hybrid seeds in an intersectional cross through post-pollination treatment of flower bases with plant growth regulators

To broaden the narrow gene base of the cultivated peanut and utilize sources of resistance to abiotic/biotic stresses, quality-related traits and high yielding factors, much attention has been paid to wild relatives of the oilseed crop since 1980s. Species outside section Arachis are cross-incompatible with A. hypogaea L.; even some of the species from section Arachis, which are supposed to be compatible, may also encounter obstacles when crossed with the peanut cultigen. The objective of the present communication is to study the effects of simple hormone treatment on production of true incompatible hybrids in peanut to replace the tedious and lengthy in vitro embryo rescue procedures currently in use. In the incompatible cross, A. hypogaea cv Qunyu 101?×?A. paraguariensis, post-pollination application of a hormone aqueous solution (IAA 4?mg/L?+?GA 2?mg/L) at flower bases resulted in 42 seeds, of which 26 were identified as true hybrids by allele-specific PCR for FAD2A genotyping. As a desirable alternative to in vitro embryo/ovules/peg culture, the present method may facilitate the utilization of wild species in peanut breeding. The method described here for peanut may be of reference to other crop plants where embryo abortion is also a problem.     

Abundant Microsatellite Diversity and Oil Content in Wild Arachis Species

The peanut (Arachis hypogaea) is an important oil crop. Breeding for high oil content is becoming increasingly important. Wild Arachis species have been reported to harbor genes for many valuable traits that may enable the improvement of cultivated Arachis hypogaea, such as resistance to pests and disease. However, only limited information is available on variation in oil content. In the present study, a collection of 72 wild Arachis accessions representing 19 species and 3 cultivated peanut accessions were genotyped using 136 genome-wide SSR markers and phenotyped for oil content over three growing seasons. The wild Arachis accessions showed abundant diversity across the 19 species. A. duranensis exhibited the highest diversity, with a Shannon-Weaver diversity index of 0.35. A total of 129 unique alleles were detected in the species studied. A. rigonii exhibited the largest number of unique alleles (75), indicating that this species is highly differentiated. AMOVA and genetic distance analyses confirmed the genetic differentiation between the wild Arachis species. The majority of SSR alleles were detected exclusively in the wild species and not in A. hypogaea, indicating that directional selection or the hitchhiking effect has played an important role in the domestication of the cultivated peanut. The 75 accessions were grouped into three clusters based on population structure and phylogenic analysis, consistent with their taxonomic sections, species and genome types. A. villosa and A. batizocoi were grouped with A. hypogaea, suggesting the close relationship between these two diploid wild species and the cultivated peanut. Considerable phenotypic variation in oil content was observed among different sections and species. Nine alleles were identified as associated with oil content based on association analysis, of these, three alleles were associated with higher oil content but were absent in the cultivated peanut. The results demonstrated that there is great potential to increase the oil content in A. hypogaea by using the wild Arachis germplasm.     

Effects of Growth Regulators on Incompatible Crosses in the Genus Arachis L.

Wild species in the genus A rachis L. have several desirablecharacters and are therefore of great interest for use in thegenetic improvement of A. hypogaea L. but only a few closelyrelated species have been used. There are many others whichcould not be used because they are incompatible with the cultivatedspecies. This paper reports techniques to produce hybrids fromincompatible crosses.     

Species relationships among the wild B genome of Arachis species (section Arachis) based on FISH mapping of rDNA loci and heterochromatin detection: a new proposal for genome arrangement

Arachis hypogaea is an allotetraploid species with low genetic variability. Its closest relatives, all of the genus Arachis, are important sources of alleles for peanut breeding. However, a better understanding of the genome constitution of the species and of the relationships among taxa is needed for the effective use of the secondary gene pool of Arachis. In the present work, we focused on all 11 non-A genome (or B genome sensu lato) species of Arachis recognized so far. Detailed karyotypes were developed by heterochromatin detection and mapping of the 5S and the 18S–25S rRNA using FISH. On the basis of outstanding differences observed in the karyotype structures, we propose segregating the non-A genome taxa into three genomes: B sensu stricto (s.s.), F and K. The B genome s.s. is deprived of centromeric heterochromatin and is homologous to one of the A. hypogaea complements. The other two genomes have centromeric bands on most of the chromosomes, but differ in the amount and distribution of heterochromatin. This organization is supported by previously published data on molecular markers, cross compatibility assays and bivalent formation at meiosis in interspecific hybrids. The geographic structure of the karyotype variability observed also reflects that each genome group may constitute lineages that have evolved through independent evolutionary pathways. In the present study, we confirmed that Arachis ipaensis was the most probable B genome donor for A. hypogaea, and we identified a group of other closely related species. The data provided here will facilitate the identification of the most suitable species for the development of prebreeding materials for further improvement of cultivated peanut.     

Variation of isozyme patterns among Arachis species

The genus Arachis contains a large number of species and undescribed taxa with patterns of genetic variation that are little understood. The objectives of this investigation were to estimate genetic diversity among species of Arachis by utilizing electrophoretic techniques and to establish the potential for use of isozymes as markers for germplasm introgression. One-hundred-and-thirteen accessions representing six of the seven sections of the genus were analyzed for isozyme variation of 17 enzymes. Section Rhizomatosae species were not included because they produce very few seeds. Seeds were macerated and the crude extract was used for starch-gel electrophoretic analyses. Although the cultivated species has few polymorphic isozymes, the diploid species are highly variable and two-to-six bands were observed for each isozyme among accessions. Because of the large number of isozyme differences between A. hypogaea and A. batizocoi (the presumed donor of the B genome), this species can no longer be considered as a progenitor of the cultivated peanut. Seed-to-seed polymorphisms within many accessions were also observed which indicate that germplasm should be maintained as bulk seed lots, representative of many individuals, or as lines from individual plants from original field collections. The area of greatest interspecific genetic diversity was in Mato Grosso, Brazil; however, the probability of finding unique alleles from those observed in A. hypogaea was greatest in north, north-central, south and southeast Brazil. The large number of polymorphic loci should be useful as genetic markers for interspecific hybridization studies.     

A single dominant gene for Fusarium wilt resistance in protoplast-derived tomato plants

Summary Autotetraploids were established from 8 diploid wild species of section Arachis. In all the autotetraploids the chromosomes paired largely as bivalents even though they possess the ability to pair as multivalents. Pollen and pod fertility in the C₁ generation were not directly associated with chromosome pairing. The C₂ generation autotetraploids showed a gradual increase in bivalent associations and pollen and pod fertility. The identification of two genomes, A and B, in the diploid species and in the tetraploid, A. hypogaea, of the section Arachis, a fairly good crossability, and the type of chromosome associations observed in hybrids between A. hypogaea and the autotetraploids of wild Arachis species indicated good prospects of utilizing autotetraploids as genetic bridges in transferring desired traits from these taxa into groundnut.Submitted as Journal Article No. 516 by International Crops Research Institute for the Semi-Arid Tropics (ICRISAT)     

Characterization and transferability of microsatellite markers of the cultivated peanut (<Emphasis Type="Italic">Arachis hypogaea</Emphasis>)

Background  

The genus Arachis includes Arachis hypogaea (cultivated peanut) and wild species that are used in peanut breeding or as forage. Molecular markers have been employed in several studies of this genus, but microsatellite markers have only been used in few investigations. Microsatellites are very informative and are useful to assess genetic variability, analyze mating systems and in genetic mapping. The objectives of this study were to develop A. hypogaea microsatellite loci and to evaluate the transferability of these markers to other Arachis species.     

Early life traits of farm and wild Atlantic salmon Salmo salar and first generation hybrids in the south coast of Newfoundland

This study examined fertilization rates, survival and early life‐trait differences of pure farm, wild and first generation (F1) hybrid origin embryos after crossing farm and wild Atlantic salmon Salmo salar. Results show that despite a trend towards higher in vitro fertilization success for wild females, differences in fertilization success in river water are not significantly different among crosses. In a hatchery environment, wild females' progeny (pure wild and hybrids with wild maternal parent) hatched 7–11 days earlier than pure farm crosses and hybrids with farm maternal parents. In addition, pure wild progeny had higher total lengths (L_T) at hatch than pure farm crosses and hybrids. Directions in trait differences need to be tested in a river environment, but results clearly show the maternal influence on early stages beyond egg‐size differences. Differences in L_T were no longer significant at 70 days post hatch (shortly after the onset of exogenous feeding) showing the need to investigate later developmental stages to better assess somatic growth disparities due to genetic differences. Higher mortality rates of the most likely hybrids (farm female × wild male hybrids) at egg and fry stages and their delayed hatch suggest that these F1 hybrids might be less likely to survive the early larval stages than wild stocks.     

REPRODUCTIVE ISOLATION OF TRITICUM BOEOTICUM AND TRITICUM URARTU AND THE ORIGIN OF THE TETRAPLOID WHEATS

The diploid wheats Triticum boeoticum and T. urartu are sympatric with one another throughout the geographic range of the wild tetraploids. Reciprocal crosses between ecogeographic types within each diploid species gave viable seed, but interspecific crosses consistently gave viable seed only when T. boeoticum was the female parent. Apparently urartu cytoplasm in combination with the boeoticum genome resulted in nonviable seed. The endosperm failed to develop normally despite regular endosperm fertilization. The F₁ plants obtained were completely self sterile although they showed regular intergenomic pairing (7II) at meiosis. Presumably the accumulation of cryptic differences between the two closely related genomes under reproductive isolation accounts for this sterility. The same accumulated cryptic differences could largely account for the preferential diploid pairing in the tetrapolid wheats which presumably were derived from such hybrids by chromosome doubling. The behavior of reciprocal crosses between the diploids and tetraploids suggested that T. boeoticum contributed the cytoplasm to both of the wild tetraploid species.     

Profiling microRNA expression in Arabidopsis pollen using microRNA array and real-time PCR

Background

Arachis hypogaea (peanut) is an important crop worldwide, being mostly used for edible oil production, direct consumption and animal feed. Cultivated peanut is an allotetraploid species with two different genome components, A and B. Genetic linkage maps can greatly assist molecular breeding and genomic studies. However, the development of linkage maps for A. hypogaea is difficult because it has very low levels of polymorphism. This can be overcome by the utilization of wild species of Arachis, which present the A- and B-genomes in the diploid state, and show high levels of genetic variability.

Results

In this work, we constructed a B-genome linkage map, which will complement the previously published map for the A-genome of Arachis, and produced an entire framework for the tetraploid genome. This map is based on an F₂ population of 93 individuals obtained from the cross between the diploid A. ipaënsis (K30076) and the closely related A. magna (K30097), the former species being the most probable B genome donor to cultivated peanut. In spite of being classified as different species, the parents showed high crossability and relatively low polymorphism (22.3%), compared to other interspecific crosses. The map has 10 linkage groups, with 149 loci spanning a total map distance of 1,294 cM. The microsatellite markers utilized, developed for other Arachis species, showed high transferability (81.7%). Segregation distortion was 21.5%. This B-genome map was compared to the A-genome map using 51 common markers, revealing a high degree of synteny between both genomes.

Conclusion

The development of genetic maps for Arachis diploid wild species with A- and B-genomes effectively provides a genetic map for the tetraploid cultivated peanut in two separate diploid components and is a significant advance towards the construction of a transferable reference map for Arachis. Additionally, we were able to identify affinities of some Arachis linkage groups with Medicago truncatula, which will allow the transfer of information from the nearly-complete genome sequences of this model legume to the peanut crop.     

Genomic affinities in Arachis section Arachis (Fabaceae): molecular and cytogenetic evidence

Section Arachis is the largest of nine sections in the genus Arachis and includes domesticated peanut, A. hypogaea L. Most species are diploids (x=10) with two tetraploids and a few aneuploids. Three genome types have been recognized in this section (A, B and D), but the genomes are not well characterized and relationships of several newly described species are uncertain. To clarify genomic relationships in section Arachis, cytogenetic information and molecular data from amplified fragment length polymorphism (AFLP) and the trnT-F plastid region were used to provide an additional insight into genome composition and species relationships. Cytogenetic information supports earlier observations on genome types of A. cruziana, A. herzogii, A. kempff-mercadoi and A. kuhlmannii but was inconclusive about the genome composition of A. benensis, A. hoehnei, A. ipaensis, A. palustris, A. praecox and A. williamsii. An AFLP dendrogram resolved species into four major clusters and showed A. hypogaea grouping closely with A. ipaensis and A. williamsii. Sequence data of the trnT-F region provided genome-specific information and showed for the first time that the B and D genomes are more closely related to each other than to the A genome. Integration of information from cytogenetics and biparentally and maternally inherited genomic regions show promise in understanding genome types and relationships in Arachis.     

Interspecific Hybridization in the Genus Dioscorea

Interspecific hybridization between Dioscorea alata (2n = 60).D. deltoidea (2n = 20), D. floribunda (2n = 36), D. composita(2n = 36), and D. friedrichsthallii (2n = 36) has revealed levelsof crossability consisting of successful crossing and normalgermination of hybrid seeds, successful crossing but poor germinationof hybrid seeds, crosses not successful due to a pre-fertilizationovular breakdown, and crosses not successful due to post-fertilizationovular breakdown. In general the three Central American species with basic chromosomenumber as 9, namely D. floribunda, D. composita, and D. friedrichsthalliiare cross compatible. In crosses involving D. floribunda withD. composita and D. floribunda with D. friedrichsthallii viablehybrids were obtained. The cross between D. friedrichsthalliiand D. composita is also successful but germination of the hybridseeds is greatly reduced. The cross of D. composita female withthe male D. friedrichsthallii was an exception to the generalcompatibility between these three species. In this cross thefertilized embryo aborted after attaining four-celled stage. The crosses between the two Old World species with basic chromosomenumber as 10, namely D. alata and D. deltoidea with each otherand with the above named three Central American species werenot successful. D. alata had pollen grains which rarely germinated.When D. alata was used as the female parent, the pollen tubesof other species grew down the style but no fertilization tookplace. The reciprocal crosses of D. deltoidea with the CentralAmerican species gave differential results. When D. deltoideawas used as the female parent no fertilization took place. However,when D. deltoidea was used as the male parent the fertilizedembryo aborted after attaining globular stage.