A Single Amino Acid Difference Is Sufficient to Elicit Vegetative Incompatibility in the Fungus Podospora Anserina

Vegetative incompatibility is known to limit heterokaryosis in filamentous fungi. It results from genetic differences between incompatible strains at specific loci. The proteins encoded by the two incompatible alleles het-s and het-S of the fungus Podospora anserina differ from each other by 14 amino acids. Two approaches have been used to identify how many and which of these differences are necessary to elicit incompatibility. Twelve alleles of the het-s locus of wild-type isolates of P. anserina and of the related species Podospora comata have been sequenced to determine the extent of the variability of genes controlling s and S specificities. Expression of hybrid het-s/het-S genes and site-specific mutagenesis revealed that the specificities of het-s and het-S are under the control of a limited number of amino acid differences. The results show that vegetative incompatibility between s and S strains can be attributed to a single amino acid difference in the proteins encoded by the het-s locus.     

Mutational analysis of the [Het-s] prion analog of Podospora anserina. A short N-terminal peptide allows prion propagation

The het-s locus is one of nine known het (heterokaryon incompatibility) loci of the fungus Podospora anserina. This locus exists as two wild-type alleles, het-s and het-S, which encode 289 amino acid proteins differing at 13 amino acid positions. The het-s and het-S alleles are incompatible as their coexpression in the same cytoplasm causes a characteristic cell death reaction. We have proposed that the HET-s protein is a prion analog. Strains of the het-s genotype exist in two phenotypic states, the neutral [Het-s*] and the active [Het-s] phenotype. The [Het-s] phenotype is infectious and is transmitted to [Het-s*] strains through cytoplasmic contact. het-s and het-S were associated in a single haploid nucleus to generate a self-incompatible strain that displays a restricted and abnormal growth. In the present article we report the molecular characterization of a collection of mutants that restore the ability of this self-incompatible strain to grow. We also describe the functional analysis of a series of deletion constructs and site-directed mutants. Together, these analyses define positions critical for reactivity and allele specificity. We show that a 112-amino-acid-long N-terminal peptide of HET-s retains [Het-s] activity. Moreover, expression of a mutant het-s allele truncated at position 26 is sufficient to allow propagation of the [Het-s] prion analog.     

Non-mendelian inheritance of the HET-s prion or HET-s prion domains determines the het-S spore killing system in Podospora anserina

Two alleles of the het-s/S locus occur naturally in the filamentous fungus Podospora anserina, het-s and het-S. The het-s encoded protein can form a prion that propagates a self-perpetuating amyloid aggregate, resulting in two phenotypes for the het-s strains. The prion-infected [Het-s] shows an antagonistic interaction to het-S whereas the prion-free [Het-s*] is neutral in interaction to het-S. The antagonism between [Het-s] and het-S is seen as heterokaryon incompatibility at the somatic level and as het-S spore killing in the sexual cycle. Two different domains of the HET-s and HET-S proteins have been identified, and a structure-function relationship has been established for interactions at the somatic level. In this study, we correlate accumulation of the HET-s and HET-S proteins (visualized using GFP) during the sexual cycle with timing of het-S spore abortion. Also, we present the structure-function relationship of the HET-s domains for interactions in the sexual cycle. We show that the constructs that ensure het-s incompatibility function in somatic mycelium are also active in het-S spore killing in the sexual cycle. In addition, paternal prion transmission and het-S spore killing has been found with the HET-s(157-289) truncated protein. The consequences of the unique transition from a coenocytic to a cellular state in the sexual phase and the timing, and localization of paternal and maternal HET-s and HET-S expression that are pertinent to prion transmission, and het-S spore killing are elaborated. These data further support our previously proposed model for het-S spore killing.     

Life history mediates mate limitation and population viability in self‐incompatible plant species

Genetically controlled self‐incompatibility systems represent links between genetic diversity and plant demography with the potential to directly impact on population dynamics. We use an individual‐based spatial simulation to investigate the demographic and genetic consequences of different self‐incompatibility systems for plants that vary in reproductive capacity and lifespan. The results support the idea that, in the absence of inbreeding effects, populations of self‐incompatible species will often be smaller and less viable than self‐compatible species, particularly for shorter‐lived organisms or where potential fecundity is low. At high ovule production and low mortality, self‐incompatible and self‐compatible species are demographically similar, thus self‐incompatibility does not automatically lead to reduced mate availability or population viability. Overall, sporophytic codominant self‐incompatibility was more limiting than gametophytic or sporophytic dominant systems, which generally behaved in a similar fashion. Under a narrow range of conditions, the sporophytic dominant system maintained marginally greater mate availability owing to the production of S locus homozygotes. While self‐incompatibility reduces population size and persistence for a broad range of conditions, the actual number of S alleles, beyond that required for reproduction, is important for only a subset of life histories. For these situations, results suggest that addition of new S alleles may result in significant demographic rescue.     

On plasmid incompatibility

In this paper is presented a brief review of the current state of information on plasmid incompatibility followed by a detailed mathematical model dealing with incompatibility between autonomous homogenic plasmids and based on the assumption that the intracellular plasmid copy pool is randomized with respect to assortment during cell division. Two cases are considered: one in which each plasmid copy replicates once in each generation of cell growth (regular replication) and one in which plasmids are chosen at random for replication from a common pool, irrespective of their replication history (random replication). In both cases, it is assumed that the partition of plasmid copies to daughter cells at cell division is regular—existing plasmid copies are divided equally among the two daughter cells (equipartition). In the case of regular replication coupled with equipartition, it is shown that the survival of heteroplasmid cells (cells containing at least one copy of each of two incompatible plasmids) during exponential growth in a nonselective medium is given by H = H₀[1 − 1/(2N − 1)]ⁿ, where H₀ and H are the numbers of heteroplasmid cells after 0 and n generations of growth, respectively, and N is the plasmid copy number in newborn cells. In the second case, (random replication-equipartition), it is shown that the survival of the heteroplasmid population during exponential growth under nonselective conditions is given by H = H₀[(N − 1)(2N + 1)/(2N − 1)(N + 1)ⁿ. Sample calculations are presented to show that segregation is more rapid in the latter than in the former case. Finally, some of the plasmid-linked genetic determinants that might be expected to affect the expression of incompatibility between nonisogenic plasmids are briefly considered. These determinants include recognition specificity for replication origins, recognition specificity, specific activity of copy number control systems, and recognition specificity of partition systems.     

Significant differences in outcrossing rate,self‐incompatibility,and inbreeding depression between two widely hybridizing species of Geum

Geum urbanum and Geum rivale are two widely hybridizing perennial herbs. Estimation of the breeding systems of these taxa using nuclear microsatellite markers scored in mother–progeny arrays demonstrated that, in pure populations, G. urbanum is predominantly selfing (outcrossing rate, t = 0.058 to 0.177), whereas G. rivale is predominantly outcrossing (t = 0.686–0.775). Theory suggests that hybridization between inbreeding and outcrossing species can potentially generate novel inbreeding lineages. However, the establishment of such lineages may be restricted either by self‐incompatibility loci or deleterious recessive alleles derived from the outcrossing parent. To assess the likelihood that hybridization between G. urbanum and G. rivale will generate novel inbreeding lineages, self‐incompatibility and inbreeding depression were investigated in the two taxa. Seed set in the absence of pollinators, and after controlled self‐ and cross‐pollination, was measured to study self‐incompatibility. Inbreeding depression was measured by estimating the relative fitness of offspring from controlled self‐and cross‐pollinations. Geum urbanum was fully self‐compatible [self‐compatibility index (SCI) = 1] and bagged flowers showed full seed set. By contrast, only 3% of bagged flowers set seed in G. rivale and controlled self‐pollinations showed a 60–80% reduction in seed set compared to controlled outcross pollinations (SCI = 0.28). There was no evidence for inbreeding depression in G. urbanum, although significant, albeit low levels of inbreeding depression were detected in one of two G. rivale populations (δ = 0.33). The implication of these results is that if genetic material from G. rivale was incorporated into a hybrid with a selfing morphology, the establishment of this selfing lineage could be compromised by self‐incompatibility and inbreeding depression. The wider implications of these results for evolution in hybrid swarms between G. urbanum and G. rivale are discussed. © 2010 The Linnean Society of London, Biological Journal of the Linnean Society, 2010, 101 , 977–990.     

Evidence for autonomous selfing in grassland Protea species (Proteaceae)

It has been assumed that species of the large African genus Protea have strong self‐incompatibility systems. However, this assumption was based largely on studies conducted on a clade of bird‐pollinated species that occur in the shrubby fynbos vegetation of the Cape region of southern Africa. To test whether self‐incompatibility occurs in a grassland/savanna Protea clade, which is largely insect‐pollinated, we performed controlled pollination experiments on four species, P. caffra, P. dracomontana, P. simplex and P. welwitschii. Although pollen–ovule ratios of all four species fall within the range for outcrossers, all four species are self‐compatible and capable of autonomous seed production. Using fluorescence microscopy, we found that self‐pollen tubes had the same probability of reaching ovules as cross‐pollen tubes. In the small tree P. caffra, selfed progeny had rates of germination and survivorship that were identical to those of crossed progeny. The grassland Protea spp. studied are likely to have mixed mating systems on account of being both visited by insects and capable of autonomous selfing. If one assumes previous reports of self‐incompatibility in Protea to be reliable, there have been at least five losses of self‐incompatibility and two gains of autonomous selfing in this genus. However, earlier studies in the genus were often methodologically flawed and a thorough re‐analysis of breeding systems in Protea is required. © 2012 The Linnean Society of London, Botanical Journal of the Linnean Society, 2012, 169 , 433–446.     

GENOME‐WIDE INVESTIGATION OF REPRODUCTIVE ISOLATION IN EXPERIMENTAL LINEAGES AND NATURAL SPECIES OF NEUROSPORA: IDENTIFYING CANDIDATE REGIONS BY MICROARRAY‐BASED GENOTYPING AND MAPPING

Inherent incompatibilities between genetic components from genomes of different species may cause intrinsic reproductive isolation. In evolution experiments designed to instigate speciation in laboratory populations of the filamentous fungus Neurospora, we previously discovered a pair of incompatibility loci (dfe and dma) that interact negatively to cause severe defects in sexual reproduction. Here we show that the dfe‐dma incompatibility also is a significant cause of genetic isolation between two naturally occurring species of Neurospora (N. crassa and N. intermedia). The strong incompatibility interaction has a simple genetic basis (two biallelic loci) and antagonistic epistasis occurs between heterospecific alleles only, consistent with the Dobzhansky–Muller model of genic incompatibility. We developed microarray‐based, restriction‐site associated DNA (RAD) markers that identified ～1500 polymorphisms between the genomes of the two species, and constructed the first interspecific physical map of Neurospora. With this new mapping resource, the approximate genomic locations of the incompatibility loci were determined using three different approaches: genome scanning, bulk‐segregant analyses, and introgression. These population, quantitative, and classical genetics methods concordantly identified two candidate regions, narrowing the search for each incompatibility locus to only ～2% of the nuclear genome. This study demonstrates how advances in high‐throughput, genome‐wide genotyping can be applied to mapping reproductive isolation genes and speciation research.     

INTERSPECIFIC INCOMPATIBILITY IN SOLANUM SPECIES

Pandey , K.K. (Crop Res. Div., D.S. & I.R., Lincoln, Christchurch, New Zealand.) Interspecific incompatibility in Solanum species. Amer. Jour. Bot. 49(8): 874–882. Illus. 1962.—A diallel cross involving 11 self-incompatible and 3 self-compatible species of Solanum was made to study the genetic basis of interspecific incompatibility. Interspecific incompatibility was not limited to crosses in which a self-compatible species was used as the male parent onto a self-incompatible species (unilateral incompatibility). A number of crosses between self-incompatible species were incompatible. In one cross, Q vernei X verrucosum, a self-compatible species was successful as a pollen parent with a self-incompatible species. Unlike other hybrids between self-compatible and self-incompatible species, which are self-incompatible, these F₁ hybrids were self-fertile, and cross-fertile among themselves and with both parents. The self-fertile S. polyadenium was cross-incompatible as a female as well as a male parent with all other species. It is suggested that the unilateral incompatibility is a property of the allele S_C which originated as a consequence of one kind of breakdown of the S_I gene; the S_C allele produces “bare” pollen growth substances which are inactivated in an incompatible style. It is proposed that the failure of the principle of unilateral interspecific incompatibility in solanaceous species may be due to the action of alleles at the second incompatibility locus revealed in certain Mexican species. It is assumed that the South American species are selected intraspecifically only for the action of S alleles but that in certain interspecific crosses and rarely in intraspecific crosses the alleles at the second locus may be expressed, thus interfering with the usual action of S alleles. The F₁ hybrids Q verrucosum (self-fertile) X simplicifolium (self-sterile) were self-incompatible at the tetraploid as well as the diploid level, and their cross-compatibility behavior was consistent with the expected activity of the S_C and S_I alleles of the 2 parents respectively.     

Identification of self-incompatibility groups in<Emphasis Type="Italic"> Hatiora</Emphasis> and<Emphasis Type="Italic"> Schlumbergera</Emphasis> (Cactaceae)

The Cactaceae, a family of about 1,800 species of succulent perennials, contains numerous species that exhibit self-incompatibility (SI). The objective of the current study was to determine the number of incompatibility groups present among diploid (2n=2x=22) cultivars of the genera Schlumbergera Lem. (Christmas cacti) and Hatiora Britton & Rose (Easter cacti). Two partial diallel crosses were performed, one with 19 cultivars of Christmas cacti [= S. truncata (Haworth) Moran and S. × buckleyi (Buckley) Tjaden] and the other with 10 cultivars of Easter cacti [= H. gaertneri (Regel) Barthlott, H. rosea (Lagerheim) Barthlott, and H. × graeseri Barthlott ex D. Hunt]. The compatibility/incompatibility status of crosses was determined by percent fruit set and presence of seed in mature fruit. None of the cultivars set fruit when selfed or crossed with a cultivar in the same incompatibility group, but fruit set ranged from 35% to 100% following compatible crosses. For the Christmas cacti, eight intra-incompatible but reciprocally compatible groups were identified, with 13 of the 19 cultivars assigned to three incompatibility groups (68%). The ten cultivars of Easter cacti yielded nine intra-incompatible but reciprocally compatible groups, with two cultivars in one incompatibility group and the other eight cultivars each assigned to a unique group. One cultivar of Christmas cactus ('Abendroth 6') was incompatible when crossed as a male with cultivars in incompatibility group 2 but was compatible in reciprocal crosses, results that suggest that this cultivar is an S-allele homozygote. The crossing relationships are consistent with a one-locus, gametophytic SI system with multiple alleles. Allozyme locus Lap-1, shown previously to be linked with the S locus (recombination frequency 7%) in Schlumbergera, exhibited insufficient allelic diversity for determining the S genotypes of the 19 cultivars of Christmas cacti. Based on the number of incompatibility groups in each diallel, at least five S-alleles occur in the 19 Christmas cacti and the 10 Easter cacti.Publication 3337 of the Massachusetts Agricultural Experiment Station. This material is based on work supported in part by the Cooperative State Research, Extension, Education Service, United States Department of Agriculture, Massachusetts Agricultural Experiment Station, under Project No. 746     

Incompatibility and pollen competition in Alnus glutinosa: Evidence from pollination experiments

Different types of incompatibility systems were found to operate simultaneously in alnus glutinosa in the course of numerous pollination experiments, including self-pollination and pollination with controlled pollen mixtures. Isozyme genetic markers were used to identify the pollen parent of each offspring from the mixed pollination experiments, thus allowing specification of the fertilization success of each pollen parent. In a first step, these results were compared with observations on in vitro pollen germination experiments. This comparison allows for exploration of the explanatory value of different germination media as models of germination conditions on stigmas. In most cases, the data suggest that the in vitro germination conditions resemble the fertilization conditions in vivo, at least in the sense that they favor the same pollen parents. By providing a generic and operable definition of the two basic types of incompatibility, eliminating (inability to fertilize ovules) and cryptic (resulting in lowered fertilization success of a pollen parent under competition), evidence was detected for the existence of both types of incompatibility in alnus glutinosa, where eliminating incompatibility occurred as self-incompatibility only. However, since this incompatibility seems to act primarily via pollen elimination, seed production is not likely to be negatively affected in natural populations, even for comparatively large amounts of self-pollination. This revised version was published online in July 2006 with corrections to the Cover Date.     

Incompatibility in someSolanum crosses

Conclusions and Summary There are four conclusions: (1)Solanum kurtzianum, S. simplicifolium andS. michoacanum possess an ordinary one locus system; (2) the three species ofMegistacroloba investigated are sufficiently closely allied to express, with little irregularity, a common incompatibility system; (3) several crosses involvingS. infundibuliforme, four wild species of the seriesTuberosa and certain cultivated diploids show a highly irregular expression of the incompatibility system which is much influenced by erratic female sterilities; and (4) the combinationS. simplificifolium x Phureja cultivar group shows an entirely anomalous behaviour (which is consistent in reciprocal) in which only three compatibility groups can be recognized in the approximate numerical ratio 121; for this there is yet no explanation.     

Transformer‐4 version 2.0.1, a free multi‐platform software to quickly reformat genotype matrices of any marker type,and archive them in the Demiurge information system

Transformer‐4 version 2.0.1 (T4) is a multi‐platform freeware programmed in java that can transform a genotype matrix in Excel or XML format into the input formats of one or several of the most commonly used population genetic software, for any possible combination of the populations that the matrix contains. T4 also allows the users to (i) draw allozyme gel interpretations for any number of diploid individuals, and then generate a genotype matrix ready to be used by T4; and (ii) produce basic reports about the data in the matrices. Furthermore, T4 is the only way to optionally submit ‘genetic diversity digests’ for publication in the Demiurge online information system ( http://www.demiurge-project.org ). Each such digest undergoes peer‐review, and it consists of a geo‐referenced data matrix in the tfm4 format plus any ancillary document or hyperlink that the digest authors see fit to include. The complementarity between T4 and Demiurge facilitates a free, safe, permanent, and standardized data archival and analysis system for researchers, and may also be a convenient resource for scientific journals, public administrations, or higher educators. T4 and its converters are freely available (at, respectively, http://www.demiurge-project.org/download_t4 and http://www.demiurge-project.org/converterstore ) upon registration in the Demiurge information system ( http://demiurge-project.org/register ). Users have to click on the link provided on an account validation email, and accept Demiurge's terms of use (see http://www.demiurge-project.org/termsofuse ). A thorough user's guide is available within T4. A 3‐min promotional video about T4 and Demiurge can be seen at http://vimeo.com/29828406 .     

Genetic analysis of novel intra-species unilateral incompatibility in Brassica rapa (syn. campestris) L.

Plants have evolved many systems to prevent inappropriate fertilization. Among them, incompatibility is a well-organized system in which pollen germination or pollen-tube growth is inhibited in pistils. Self-incompatibility (SI), rejecting self-pollen, promotes outbreeding in flowering plants. On the other hand, inter-species incompatibility, preventing gene flow among species to restrict outbreeding, usually occurs unilaterally, and is known as unilateral incompatibility (UI). In Brassicaceae, little is known about the molecular mechanism of UI, although S-locus genes involved in recognition of self-pollen have been characterized in the SI system. In the present study, we characterized novel UI observed between members of the same species, Brassica rapa; pollen of Turkish SI lines was specifically rejected by pistils of the Japanese commercial SI variety Osome. The incompatible phenotype of this intra-species UI closely resembled that of SI. Segregation analysis revealed that the pollen factor of this UI was not linked to the S-locus.The revised version was published online in December 2004 with corrections to figure 1.     

Fecundity and fitness in cross-compatible pollinations of tristylous North American Lythrum salicaria populations

As heterostyly and self incompatibility are linked in tristylous L. salicaria, all cross-compatible pollinations – those between anthers and styles of the same level – should produce viable seed. The rigor of this theory was tested using seed set and germination of cross-compatible pollinations in 18 naturalized L. salicaria populations in Minnesota/Wisconsin (n=342 genotypes; n=86 shorts, n=127 mids, and n=129 longs). Seed set for short-styled genotypes ranged from zero to 135 (36+38); mids–0–156, (53+39), and longs–0–151 (59+39). Mean seed set per capsule was not significantly different for mids and longs, but both were significantly greater than that of shorts (F=14, P<0.0001). Zero seed set frequently occurred in most compatible crosses, in contrast with theoretical expectations. The high percentage of populations deviating from normality must be due to incompatibility. An incompatibility system independent of heterostyly could cause this, where failed crosses result from matches of incompatibility specificities in pollen and pistil. This independence is questionable, however, given the non-significant difference in failed outcrosses for pooled χ² comparing within and between populations (χ²=0.395, P>0.5). A sporophytic incompatibility model is proposed with a minimum of three specificities. Zero seed set in compatible crosses is due to the addition of alleles from L. alatum, a distylous species that forms introgressive hybrids with L. salicaria. Reduced fecundity could increase the deficiency of shorts, and significantly greater seed germination of shorts could explain the continued presence of short-styled individuals in L. salicaria populations. Received: 3 February 2000 / Accepted: 25 March 2000     

Mentor pollen: Possible role of wall-held pollen growth promoting substances in overcoming intra- and interspecific incompatibility

Recent studies have shown that certain normally incompatible, interspecific combinations in the genus Populus, and intraspecific combination in Cosmos bipinnatus can be made compatible by mixing irradiation- or chemically-killed compatible pollen (mentor) with normal incompatible pollen at the time of pollination. Knox and associates have proposed that in the sporophytic system of incompatibility the compatible mentor pollen provides the so-called specific recognition substances to the incompatible pollen thereby making the latter compatible. In the present experiments mentor pollen was used in attempts to overcome both intra- and interspecific incompatibility in the genus Nicotiana which has a gametophytic intraspecific incompatibility system. Although not denying that recognition substances specific to pollenpistil incompatibility reactions are present in pollen walls, the results suggest that a role of mentor pollen in overcoming incompatibility may be to provide extra free pollen growth promoting substances (PGS). These substances are apparently able to promote just sufficient further growth to allow some fertilizations by certain pollen tubes with inherently weak expression of incompatibility.The present proposed PGS-Hypothesis also elucidates the physiological basis of the widely-held relationship found between genetic systems of self-incompatibility and sites of pollen inhibition.     

Cloning and identification of partial DNA fragment for the <Emphasis Type="Italic">B</Emphasis> mating-type factor in <Emphasis Type="Italic">Lentinula edodes</Emphasis> using degenerate PCR

The edible fungus Lentinula edodes is a heterothallic homobasidiomycete whose mating is controlled by a bifactorial incompatibility mating system determined by two unlinked factors (the A and B mating-type factors). Although this mechanism is well accepted, there is a lack of understanding about its molecular basis, as the incompatibility factors have not been cloned and sequenced. In this study, by means of degenerate PCR we obtained one 773 bp DNA fragment cosegregating with B ₂ mating-type factor in L. edodes stock HL01. Sequencing analysis revealed that it belonged to a pheromone receptor, suggesting that the genetic basis for B factor in L. edodes is the same as in the two model mushroom species, Schizophyllum commune and Coprinus cinereus, the structure and function of whose B incompatibility factors have been studied in detail. So far as we know, this is the first report about the cloning of B mating factor in L. edodes.     

Distribution of sequences homologous to the impCAB operon of TP110 among bacterial plasmids of different incompatibility groups

Summary Mutagenic DNA repair is a function of many naturally occurring plasmids belonging to several different incompatibility groups. A DNA probe corresponding to the impCAB operon of the IncIl plasmid TP110, which encodes such functions, was used to investigate the distribution of homologous sequences in both related and unrelated plasmids. Southern blotting was used to demonstrate considerable sequence conservation amongst a number of plasmid types, with imp-related sequences being found on plasmids belonging to the I1, I1/B, B and FIV incompatibility groups. However, no homology was detected amongst plasmids of the N and L/M incompatibility groups, many of which carry functionally similar gene clusters. It appears that sequences determining mutagenic repair functions have been largely conserved within any one incompatibility group, but that significant divergent evolution has occurred between groups.     

Study of the incompatibility and replication of the 70-kb virulence plasmid of Yersinia

The 70-kb virulence plasmid, vir, from four Yersinia enterocolitica and one Y. pseudotuberculosis strains are incompatible with IncFI plasmids FLac and R386 while they are compatible with plasmids representing nine other incompatibility groups. Hybridization experiments carried out on one of these virulence plasmids showed that it contains the F incompatibility determinant D, incD. This determinant was cloned onto pACYC184 and the recombinant clone expressed incompatibility with FLac. We conclude that the incompatibility observed between F or R386 and the 70-kb virulence plasmid of Y. enterocolitica and Y. pseudotuberculosis is mediated by incD. Replication genes (rep) from the same plasmid were cloned independently in Escherichia coli. Rep and incD map on two different BamHI fragments. Surprisingly, the replicon isolated is not sensitive to inc D incompatibility. Apart from incD, vir and F share extremely little homology. In particular, there is no evidence for the presence of an F-like transfer operon on vir.     

Sexual reproduction of the pentaploid,short‐styled Oxalis pes‐caprae allows the production of viable offspring

Reproduction is a key factor for the successful establishment and spread of introduced species. Oxalis pes‐caprae is a tristylous species with a self‐ and morph‐incompatibility sexual system that, in the invaded range of the western Mediterranean Basin, has been found to reproduce asexually because only the pentaploid, short‐styled morph (5x S‐morph) was introduced. The objective of this study was to test the ability of the 5x S‐morph of O. pes‐caprae to produce viable offspring in the absence of compatible mates, exploring the hypothesis that new morphs could have emerged by sexual reproduction events of the initially introduced morph. Pollen germination, pollen tube development, fruit and seed production, seed germination and offspring ploidy levels were analysed after controlled hand‐pollinations to assess self‐ and morph‐incompatibility and production of viable gametes by the 5x S‐morph. The self‐incompatibility system is still operating, but a partial breakdown in the morph‐incompatibility system combined with the production of viable gametes was observed, allowing sexual reproduction of the 5x S‐morph in the invaded range. The ability of the 5x S‐morph to reproduce sexually may have major consequences for the dynamics of invasive populations of O. pes‐caprae and could be one of the factors involved in the occurrence of new floral morphs in this invaded range.