INTERSPECIFIC HYBRIDIZATION IN THE HAPLOID BLADE‐FORMING MARINE CROP PORPHYRA (BANGIALES,RHODOPHYTA): OCCURRENCE OF ALLODIPLOIDY IN SURVIVING F1 GAMETOPHYTIC BLADES1

We performed interspecific hybridization in the haploid blade‐forming marine species (nori) of the genus Porphyra, which have a heteromorphic life cycle with a haploid gametophytic blade and a diploid microscopic sporophyte called the “conchocelis phase.” The green mutant HGT‐6 of P. tenera var. tamatsuensis A. Miura was crossed with the wildtype HG‐1 of P. yezoensis f. narawaensis A. Miura; the F₁ heterozygous conchocelis developed normally and released numerous conchospores. However, almost all the conchospore germlings did not survive past the four‐cell stage or thereabouts, and only a few germlings developed into gametophytic blades. These results indicate that hybrid breakdown occurred during the meiosis, while the surviving F₁ gametophytic blades were considered a breakthrough in the interspecific hybridization of Porphyra. Organelle genomes (cpDNA and mtDNA) were found to be maternally inherited in the interspecific hybridization by molecular analyses of the organelle DNA. In particular, molecular analyses of nuclear DNA revealed that the surviving F₁ blades were allodiploids in the haploid gametophytic phase; however, there is a possibility of the occurrence of rapid chromosomal locus elimination and rearrangement in the F₁ conchocelis phase. Our findings are noteworthy to the breeding of cultivated Porphyra and will provide important information for understanding of the speciation of marine plants with high species diversity.     

Genetic analysis of artificial pigmentation mutants in Porphyra yezoensis Ueda (Bangiales, Rhodophyta)

Porphyra yezoensis Ueda artificial pigmentation mutants, yel (green), fre (red‐orange) and bop (pink), obtained by treatment with /V‐methyl‐/V′‐nitro‐N‐nitrosoguanidine, were genetically analysed. The mutations associated with color phenotypes are recessive because all of the heterozygous conchocelis resembled the wild type color when they were crossed with the wild type (wt). In the reciprocal crosses of yel × wt, both parental colors and eight types of blades appeared in the F₁ gametophytic blades from the heterozygous conchocelis. Both colors segregated in the sectored F₁ blades in a 1:1 ratio, indicating that the color pheno‐type of yel resulted from a single mutation in the nuclear gene. In the reciprocal crosses of fre × wt, however, four colors and more than 40 types of blades appeared in the F₁ blades from the heterozygous conchocelis, indicating that the color phenotype of fre resulted from two mutations in different genes. In the reciprocal crosses of bop×wt, three colors and 12 types of blades were observed in the F₁ blades from the heterozygous conchocelis. Both parental colors appeared far more frequently than the third new color. These results indicated that the color phenotype of bop resulted from two closely linked mutations in different genes, and the epistasis occurred in the F₁ blades. The mutants, yel, fre and bop, differ from the spontaneous green (C‐O), the red (H‐25) and the violet (V‐O) mutants of P. yezoensis, respectively.     

CHIMERAS WITH MOSAIC PATTERN IN ARCHEOSPORE GERMLINGS OF PYROPIA YEZOENSIS UEDA (BANGIALES,RHODOPHYTA)1

In the marine crop Pyropia yezoensis (Ueda) M. S. Hwang et H. G. Choi, it is known that conchospores from heterozygous conchocelis develop into sectored gametophytic blades (chimeras), but archeospores asexually released from haploid blades do not usually grow into chimeric blades. In this study, chimeras with mosaic pattern consisting of the green and wildtype colors were developed from archeospores that were released from a blade piece containing a cell cluster of green color induced by heavy‐ion beam irradiation. To make clear whether these archeospores were produced from the green‐colored cells or the wildtype‐colored cells, cell clusters of the green mutant, wildtype, and mosaic pattern were cut out from the grown chimera, and archeospores were released from each of the three blade pieces. Archeospores from the green‐mutant blade piece and from the wildtype blade piece developed into only green‐mutant blades and wildtype blades, respectively. In contrast, archeospores from the blade piece with mosaic pattern developed into green‐mutant blades, wildtype blades, and chimeric blades with mosaic pattern of the two colors, although the frequency of the chimeras was low. Because each gametophytic cell possesses a single plastid, it is difficult to explain the occurrence of the new chimeras as a mutation of the plastid DNA. Thus, the new chimeras are considered to be due to transposable elements in Pyropia.     

THE EVOLUTIONARY STABILITY OF CROSS‐SEX,CROSS‐TRAIT GENETIC COVARIANCES

Although knowledge of the selective agents behind the evolution of sexual dimorphism has advanced considerably in recent years, we still lack a clear understanding of the evolutionary durability of cross‐sex genetic covariances that often constrain its evolution. We tested the relative stability of cross‐sex genetic covariances for a suite of homologous contact pheromones of the fruit fly Drosophila serrata, along a latitudinal gradient where these traits have diverged in mean. Using a Bayesian framework, which allowed us to account for uncertainty in all parameter estimates, we compared divergence in the total amount and orientation of genetic variance across populations, finding divergence in orientation but not total variance. We then statistically compared orientation divergence of within‐sex ( G ) to cross‐sex ( B ) covariance matrices. In line with a previous theoretical prediction, we find that the cross‐sex covariance matrix, B , is more variable than either within‐sex G matrix. Decomposition of B matrices into their symmetrical and nonsymmetrical components revealed that instability is linked to the degree of asymmetry. We also find that the degree of asymmetry correlates with latitude suggesting a role for spatially varying natural selection in shaping genetic constraints on the evolution of sexual dimorphism.     

ASSESSMENT OF PHOTOSYNTHETIC PERFORMANCE OF PORPHYRA YEZOENSIS (BANGIALES,RHODOPHYTA) IN CONCHOCELIS PHASE1

Photosynthetic characteristics of four Porphyra yezoensis Ueda [a taxonomic synonym of Pyropia yezoensis (Ueda) M. S. Hwang et H. G. Choi] strains in conchocelis phase were investigated and compared with one wildtype of P. yezoensis and two strains of Porphyra haitanensis T. J. Chang et B. F. Zheng [a taxonomic synonym of Pyropia haitanensis (T. J. Chang et B. F. Zheng) N. Kikuchi et M. Miyata]. Results showed that experimental strains had higher contents of chl a and carotenoids, but a lower content of total phycobiliproteins than the wildtype. Meanwhile, photochemical efficiency of PSII was measured using pulse amplitude modulation (PAM) fluorometry technology. The value of PSII photosynthetic parameters of P. yezoensis strains were all higher than the wild strain, and the maximal quantum yields (F_v/F_m), effective quantum yields Y(II), and relative photosynthetic electron transport rates (rETR) of P. haitanensis were higher than those of P. yezoensis. The present study verified the possibility of selective breeding of P. yezoensis using the filamentous sporophyte instead of the gametophytic thallus, the advantages being (i) nonrequirement of control of life cycle and (ii) direct and rapid cultivar improvement by artificial selection. We consider the method to be a promising technique for selective breeding of P. yezoensis cultivars.     

Rapid DNA extraction from conchocelis and ITS-1 rDNA sequences of seven strains of cultivated Porphyra yezoensis (Bangiales, Rhodophyta)

In order to extract DNA rapidly from cultivated Porphyra, we extracted total DNA from conchocelis using the ISOPLANT II kit (Nippon Gene) without liquid nitrogen treatment or CsCl-gradient ultracentrifugation. By confirming the reproducibility of RAPD patterns, it is concluded that the quality of the extracted DNA is sufficient to use as a template for molecular investigation. Using this rapid method, the nuclear ribosomal DNA of the internal transcribed spacer (ITS) regions was amplified from seven strains of cultivated Porphyra, which had been maintained as free-living conchocelis by subculturing in the laboratory. From the amplified DNAs, the ITS-1 sequences were determined in order to identify the species and genetic relationship of the strains. The sequences were identical in the seven strains, and all the strains were identified as P. yezoensis. Furthermore, the gametophytic blades of these strains showed long linear or oblanceolate shapes in the laboratory culture. It was concluded that these strains are P. yezoensis form. narawaensis. This rapid DNA extraction method from conchocelis will be a powerful tool for phylogenetic analysis and for genetic improvement of cultivated Porphyra.     

Genetic similarity analysis within Pyropia yezoensis blades developed from both conchospores and blade archeospores using AFLP1

Pyropia yezoensis (Ueda) M. S. Hwang et H. G. Choi (previously called Porphyra yezoensis) is an economically important alga. The blades generated from conchospores are genetic chimeras, which are not suitable for genetic similarity analysis. In this study, two types of blades from a single filament of P. yezoensis sporophyte filament were obtained. One type, ConB, consisted of 40 blades that had germinated from conchospores. The other type, ArcB, consisted of 88 blades that had germinated from archeospores released from ConB. Both of them were analyzed by amplified fragment length polymorphism. The low genetic similarity levels for both conchospore‐germinated and archeospore‐germinated blades demonstrated that the conchcelis we used was cross‐fertilized. Furthermore, a higher polymorphic loci ratio (98.6%) was detected in ArcB than in ConB (80.7%), and the average genetic similarity of ArcB (average 0.61) was lower than that of ConB (average 0.71). These differences indicated that genetic analysis using ArcB gives more accurate results.     

ALLOPOLYPLOIDY IN NATURAL AND CULTIVATED POPULATIONS OF PORPHYRA (BANGIALES,RHODOPHYTA)1

To confirm whether allopolyploidy occurs in samples of previously identified Porphyra yezoensis Ueda, P. tenera Kjellm., and P. yezoensis × P. tenera from natural and cultivated populations, we examined these samples by using PCR‐RFLP and microsatellite analyses of multiple nuclear and chloroplast regions [nuclear regions: type II DNA topoisomerase gene (TOP2), actin‐related protein 4 gene (ARP4), internal transcribed spacer (ITS) rDNA and three microsatellite loci; chloroplast region: RUBISCO spacer]. Except for the ITS region, these multiple nuclear markers indicated that the wild strain MT‐1 and the cultivated strain 90‐02 (previously identified as P. yezoensis × P. tenera and cultivated P. tenera, respectively) are heterozygous and possess both genotypes of P. tenera and P. yezoensis in the conchocelis phase. Furthermore, gametophytic blades of two pure lines, HG‐TY1 and HG‐TY2 (F₁ strains of MT‐1 and 90‐02, respectively), were also heterozygous, and six chromosomes per single cell could be observed in each blade of the two pure lines. These results demonstrate that allopolyploidy occurs in Porphyra strains derived from both natural and cultivated populations, even though ITS genotypes of these strains showed homogenization toward one parental ITS.     

Genetic structure and host–parasite co‐divergence: evidence for trait‐specific local adaptation

Host–parasite co‐evolution can lead to genetic differentiation among isolated host–parasite populations and local adaptation between parasites and their hosts. However, tests of local adaptation rarely consider multiple fitness‐related traits although focus on a single component of fitness can be misleading. Here, we concomitantly examined genetic structure and co‐divergence patterns of the trematode Coitocaecum parvum and its crustacean host Paracalliope fluviatilis among isolated populations using the mitochondrial cytochrome oxidase I gene (COI). We then performed experimental cross‐infections between two genetically divergent host–parasite populations. Both hosts and parasites displayed genetic differentiation among populations, although genetic structure was less pronounced in the parasite. Data also supported a co‐divergence scenario between C. parvum and P. fluviatilis potentially related to local co‐adaptation. Results from cross‐infections indicated that some parasite lineages seemed to be locally adapted to their sympatric (home) hosts in which they achieved higher infection and survival rates than in allopatric (away) amphipods. However, local, intrinsic host and parasite characteristics (host behavioural or immunological resistance to infections, parasite infectivity or growth rate) also influenced patterns of host–parasite interactions. For example, overall host vulnerability to C. parvum varied between populations, regardless of parasite origin (local vs. foreign), potentially swamping apparent local co‐adaptation effects. Furthermore, local adaptation effects seemed trait specific; different components of parasite fitness (infection and survival rates, growth) responded differently to cross‐infections. Overall, data show that genetic differentiation is not inevitably coupled with local adaptation, and that the latter must be interpreted with caution in a multi‐trait context.     

IDENTIFICATION OF PORPHYRA HAITANENSIS (BANGIALES,RHODOPHYTA) MEIOSIS BY SIMPLE SEQUENCE REPEAT MARKERS1

The simple sequence repeat (SSR) marks were employed to identify the stage at which meiosis occurs in the life cycle of Porphyra haitanensis T. J. Chang et B. F. Zheng. More than 90% of F1 blades of heterozygous conchocelis produced by the cross between a red mutant (R, ♀) and the wildtype (W, ♂) were color sectored. Two parental colors (R and W) and two new colors (R′ and W′) appeared in linear sectors in the color‐sectored F1 blades. Two SSR primer pairs selected from a total of 52 primer pairs generated a specific paternal and maternal fragment, respectively. Co‐occurrence of these two bands was detected in heterozygous conchocelis and in the color‐sectored F1 blades with two to four sectors, such as R + W, R′ + W′, and R′ + R + W + W′. However, the single‐colored F1 blades exhibited only one band. In the sectors isolated from the color‐sectored F1 blades, R and R′ were the same, showing the maternal pattern, whereas W and W′ were the same, showing the paternal pattern. These data suggested that the two different bands from heterozygous conchocelis originated from the parents and segregated in the F1 blades, whereas the two new colors, R′ and W′, in the F1 blades were produced by the exchange and recombination of alleles of the parental colors during meiosis. These results indicated that meiosis of P. haitanensis occurs during the first two cell divisions of a germinating conchospore, and, therefore, the initial four cells constitute a linear genetic tetrad, leading to the formation of a color‐sectored blade.     

Analysis of hybridization strains of <Emphasis Type="Italic">Porphyra</Emphasis> based on <Emphasis Type="Italic">rbc</Emphasis>L gene sequences

Two strains, which are the free-living conchocelis of Porphyra yezoensis Ueda and Porphyra haitanensis T. J. Chang et B. F. Zheng, and four “interspecific hybridization” strains of these two species are investigated. The rbcL genes of 11 samples were amplified and sequenced, each of which were about 1,400 bp with a good specificity. The results of pair-wise distance matrix and multi-alignment showed that pair-wise distance were small while homologous index was large between strains Y-2066, Y-k2001, and Y-H001. These two indexes showed the same level as the above between strains H-2001, Y-hyC₁, and Y-hyC₂; however, the distances were larger between three former strains and three latter strains. Cluster trees showed the same trend. Fertile strains appeared after 2 years of culture of unfertile interspecific hybridization conchocelis and were separated from that based on different colors. Our finding that these fertile strains can bear offspring is important for understanding the interspecies hybridization of Porphyra. Molecular analysis of the fertile strains based on rbcL gene showed maternal inheritance. We inferred that somatic recombination was one of the reasons making interspecific hybridization strains fertile.     

MORPHOLOGICAL AND MOLECULAR ANALYSIS OF THE ENDANGERED SPECIES PORPHYRA TENERA (BANGIALES,RHODOPHYTA)1

Porphyra tenera Kjellman, widely cultivated in nori farms before the development of artificial seeding, is currently listed as an endangered species in Japan. To confirm whether a wild‐collected gametophytic blade was P. tenera or the closely related species P. yezoensis Ueda, morphological observations and molecular analyses were made on the pure line HGT‐1 isolated from a wild blade. This pure line was identified as P. tenera based on detailed morphological features. Sequences of the nuclear internal transcribed spacer region 1 and the plastid RUBISCO spacer revealed that P. tenera HGT‐1 was clearly different from P. yezoensis f. narawaensis Miura, the main species cultivated in Japan. PCR‐RFLP analysis of the internal transcribed spacer region was found to be a convenient method for rapid discrimination between P. tenera and cultivated P. yezoensis. The restriction patterns generated by the endonucleases Dra I and Hae III were useful for differentiating between both gametophytic and conchocelis stages of P. tenera HGT‐1 and P. yezoensis f. narawaensis strains. Thus, PCR‐RFLP analysis will serve as a valuable tool for rapid species identification of cultivated Porphyra strains, culture collections of Porphyra strains for breeding material and conservation of biodiversity, and, as codominant cleaved amplified polymorphic sequence markers for interspecific hybridization products between P. tenera and P. yezoensis f. narawaensis. Under the same culture conditions, rate of blade length increase and the blade length‐to‐width ratio were lower in P. tenera HGT‐1 than in P. yezoensis f. narawaensis HG‐4. The HGT‐1 became mature more rapidly than HG‐4 and had thinner blades.     

GENETIC DIVERSITY AND INTROGRESSION IN TWO CULTIVATED SPECIES (PORPHYRA YEZOENSIS AND PORPHYRA TENERA) AND CLOSELY RELATED WILD SPECIES OF PORPHYRA (BANGIALES,RHODOPHYTA)1

We investigated the genetic variations of the samples that were tentatively identified as two cultivated Porphyra species (Porphyra yezoensis Ueda and Porphyra tenera Kjellm.) from various natural populations in Japan using molecular analyses of plastid and nuclear DNA. From PCR‐RFLP analyses using nuclear internal transcribed spacer (ITS) rDNA and plastid RUBISCO spacer regions and phylogenetic analyses using plastid rbcL and nuclear ITS‐1 rDNA sequences, our samples from natural populations of P. yezoensis and P. tenera showed remarkably higher genetic variations than found in strains that are currently used for cultivation. In addition, it is inferred that our samples contain four wild Porphyra species, and that three of the four species, containing Porphyra kinositae, are closely related to cultivated Porphyra species. Furthermore, our PCR‐RFLP and molecular phylogenetic analyses using both the nuclear and plastid DNA demonstrated the occurrence of plastid introgression from P. yezoensis to P. tenera and suggested the possibility of plastid introgression from cultivated P. yezoensis to wild P. yezoensis. These results imply the importance of collecting and establishing more strains of cultivated Porphyra species and related wild species from natural populations as genetic resources for further improvement of cultivated Porphyra strains.     

Characterization of a high‐growth‐rate mutant strain of Pyropia yezoensis using physiology measurement and transcriptome analysis

A mutant strain of Pyropia yezoensis, strain E, was isolated from the free‐living conchocelis of a pure strain (NA) treated with ethyl methane sulfonate. The incremental quantities of young strain E blades were higher than those of NA after 14 d of cultivation, indicating that young blades of mutant strain E released more archeospores. The mean length and weight of large E blades were both over three times greater than those of NA after 4 weeks of cultivation. The photosynthetic parameters (Fv/Fm, Y[I], Y[II], and O₂ evolution rate) and pigment contents (including phycoerythrin and phycocyanin) of strain E blades were higher than those of NA (P < 0.05). The cellular respiratory rate of strain E blades was lower than that of NA (P < 0.05). In order to investigate the causes of changes in strain E blades, total RNA in strain E and NA blades were sequenced using the Illumina Hiseq platform. Compared with NA, 1,549 unigenes were selected in strain E including 657 up‐regulated and 892 down‐regulated genes. According to the physiology measurement and differentially expressed genes analysis, cell respiration in strain E might decrease, whereas anabolic‐like photosynthesis and protein biosynthesis might increase compared with NA. This means substance accumulation might be greater than decomposition in strain E. This might explain why strain E blades showed improved growth compared with NA. In addition, several genes related to stress resistance were up‐regulated in strain E indicating that strain E might have a higher stress resistance. The sequencing dataset may be conducive to Pyropia yezoensis molecular breeding research.     

Confirmation of cultivated Porphyra tenera (Bangiales, Rhodophyta) by polymerase chain reaction restriction fragment length polymorphism analyses of the plastid and nuclear DNA

Polymerase chain reaction restriction fragment length polymorphism (PCR‐RFLP) analysis of the plastid ribulose‐1,5‐bisphosphate carboxylase (RuBisCo) spacer region was developed for a more reliable and rapid species identification of cultivated Porphyra in combination with PCR‐RFLP analysis of the nuclear internal transcribed spacer (ITS) region. From the PCR‐RFLP analyses of the plastid and nuclear DNA, we examined seven strains of conchocelis that were used for cultivation as Porphyra tenera Kjellman but without strict species identification. The PCR‐RFLP analyses suggested that two strains, C‐32 and 90‐02, were cultivated P. tenera and that the other five strains, C‐24, C‐28, C‐29, C‐30 and M‐1, were Porphyra yezoensis f. narawaensis Miura. To identify species more accurately and to reveal additional genetic variation, the two strains C‐32 and 90‐02 were further studied by sequencing their RuBisCo spacer and ITS‐1 regions. Although RuBisCo spacer sequences of the two strains were identical to each other, each of their ITS‐1 sequences showed a single substitution. The sequence data again confirmed that the two strains (C‐32 and 90‐02) were cultivated P. tenera, and suggested that the two strains showed some genetic variation. We concluded that PCR‐RFLP analysis of the plastid and nuclear DNA is a powerful tool for reliable and rapid species identification of many strains of cultivated Porphyra in Japan and for the collection of genetically variable breeding material of Porphyra.     

Mapping QTL for production traits in segregating Piétrain pig populations using genome‐wide association study results of F2 crosses

In this study, genome‐wide association study (GWAS) results of porcine F2 crosses were used to map QTL in outcross Piétrain populations. For this purpose, two F2 crosses (Piétrain × Meishan, n = 304; Piétrain × Wild Boar, n = 291) were genotyped with the PorcineSNP60v2 BeadChip and phenotyped for the dressing yield, carcass length, daily gain and drip loss traits. GWASs were conducted in the pooled F2 cross applying single marker mixed linear models. For the investigated traits, between two and five (in total 15) QTL core regions, spanning 250 segregating SNPs around a significant trait‐associated peak SNP, were identified. The SNPs within the QTL core regions were subsequently tested for trait association in two outcross Piétrain populations consisting of 771 progeny‐tested boars and 210 sows with their own performance records. In the sow (boar) dataset, five (eight) of the 15 mapped QTL were validated. Hence, many QTL mapped in the F2 crosses (with Piétrain as a common founder breed) are still segregating in the current Piétrain breed. This confirms the usefulness of existing F2 crosses for mapping QTL that are still segregating in the recent founder breed generation. The approach utilizes the high power of an F2 cross to map QTL in a breeding population for which it is not guaranteed that they would be found using a GWAS in this population.     

PRODUCTIVITY AND DIVERSITY IN A CROSS‐FEEDING POPULATION OF ARTIFICIAL ORGANISMS

Cross‐feeding interactions are a common feature of many microbial systems, such as colonies of Escherichia coli grown on a single limiting resource, and microbial consortia cooperatively degrading complex compounds. We have studied this phenomenon from an abstract point of view by considering artificial organisms that metabolize binary strings from a shared environment. The organisms are represented as simple cellular automaton rules and the analog of energy in the system is an approximation of the Shannon entropy of the binary strings. Only organisms that increase the entropy of the transformed strings are allowed to replicate. This system exhibits a large degree of species diversity, which increases when the flow of binary strings into the system is reduced. Investigating the relation between ecosystem productivity and diversity we find that diversity is negatively correlated with biomass production and energy uptake, while it correlates positively with energy‐uptake efficiency. By performing invasion experiments, we show that the source of diversity is negative frequency‐dependent selection acting among the different species, and that some of these interactions are intransitive, another mechanism known to promote diversity.     

CHEMICAL COMPOSITION AND STRUCTURE OF THE CELL WALLS OF THE CONCHOCELIS AND THALLUS PHASES OF PORPHYRA TENERA (RHODOPHYCEAE)1,2

Purified cell walls were prepared from both the conchocelis and thallus phases of Porphyra tenera (Kjellm.). The nitrogen content of cell walls from the conchocelis was significantly greater than that for the thallus cell walls, being 3.35 ± 0.26% and 2.39± 0.03%, respectively. Amino acid analysis revealed important differences. The conchocelis cell wall hydrolyzates were richer in aspartic acid, glutamic acid, methionine, and basic amino acids. The thallus cell wall hydrolyzates, however, contained much more glycine and alanine than did those of the conchocelis. Hydroxyproline was not detected in cell walls of either phase. The neutral sugar content of cell wall hydrolyzates from the thallus was more than double that from the conchocelis being 83.6% and 34.5%, respectively. The former contained predominantly mannose which accounted for 72.2% of the neutral sugars while the latter was principally galactose (49.9%) and glucose (36.4%). Methylation analysis confirmed the presence of cellulose microfibrils in the conchocelis in contrast to xylan microfibrils in the thallus. The results establish that the conchocelis and thallus phases of P. tenera differ markedly in the structure and composition of the cell walls.     

Mixed pollen load and late‐acting self‐incompatibility flexibility in Adenocalymma peregrinum (Miers) L.G. Lohmann (Bignonieae: Bignoniaceae)

• Mixed cross and self‐pollen load on the stigma (mixed pollination) of species with late‐acting self‐incompatibility system (LSI) can lead to self‐fertilized seed production. This “cryptic self‐fertility” may allow selfed seedling development in species otherwise largely self‐sterile. Our aims were to check if mixed pollinations would lead to fruit set in LSI Adenocalymma peregrinum, and test for evidence of early‐acting inbreeding depression in putative selfed seeds from mixed pollinations.
• Experimental pollinations were carried out in a natural population. Fruit and seed set from self‐, cross and mixed pollinations were analysed. Further germination tests were carried out for the seeds obtained from treatments.
• Our results confirm self‐incompatibility, and fruit set from cross‐pollinations was three‐fold that from mixed pollinations. This low fruit set in mixed pollinations is most likely due to a greater number of self‐ than cross‐fertilized ovules, which promotes LSI action and pistil abortion. Likewise, higher percentage of empty seeds in surviving fruits from mixed pollinations compared with cross‐pollinations is probably due to ovule discounting caused by self‐fertilization. Moreover, germinability of seeds with developed embryos was lower in fruits from mixed than from cross‐pollinations, and the non‐viable seeds from mixed pollinations showed one‐third of the mass of those from cross‐pollinations.
• The great number of empty seeds, lower germinability, lower mass of non‐viable seeds, and higher variation in seed mass distribution in mixed pollinations, strongly suggests early‐acing inbreeding depression in putative selfed seeds. In this sense, LSI and inbreeding depression acting together probably constrain self‐fertilized seedling establishment in A. peregrinum.