Paternal bottlenecks in fragmented populations of the 
grassland daisy Rutidosis leptorrhynchoides

Allozyme markers were used to estimate mating system parameters in nine fragmented populations of the grassland daisy Rutidosis leptorrhynchoides that differed in size and spatial isolation. Multilocus estimates of outcrossing rate did not differ significantly among populations, all indicating a high level of outcrossing (tm=0·84–1·0). Small populations showed greater divergence than large populations between the allele frequencies in the population and those in the pollen pool, indicating paternal bottlenecks. Isolated populations of fewer than 200 individuals also exhibited higher correlations of outcrossed paternity (rp) than larger populations, indicating the production of more full-sibs within families. The combination of paternal bottlenecks and correlated paternity increases the genetic identity of progeny across families and predisposes populations to biparental inbreeding in subsequent generations. As over half the remaining populations of R. leptorrhynchoides contain fewer than 200 plants, such second-order inbreeding may threaten the viability of the species if it is associated with significant inbreeding depression.

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Effect of forest fragmentation and altitude on the mating system of Eucalyptus pauciflora (Myrtaceae)

Australian Journal of Botany ◽

10.1071/bt13259 ◽

2013 ◽

Vol 61 (8) ◽

pp. 622 ◽

Cited By ~ 7

Author(s):

Archana Gauli ◽

René E. Vaillancourt ◽

Dorothy A. Steane ◽

Tanya G. Bailey ◽

Brad M. Potts

Keyword(s):

Habitat Fragmentation ◽

Population Density ◽

Mating System ◽

Forest Restoration ◽

Outcrossing Rate ◽

Self Incompatibility ◽

Fragmented Populations ◽

System Parameters ◽

Key Factor ◽

Seed Yields

Habitat fragmentation is a key factor causing variation in important mating system parameters in plants, but its effect is variable. We studied mating system variation among 276 native trees from 37 populations of Eucalyptus pauciflora from Tasmania. We assayed 10 microsatellite loci from 1359 open-pollinated progeny from these trees. Across Tasmania the species’ mating system was characterised by a high outcrossing rate (tm = 0.90) but moderate bi-parental inbreeding (tm–ts = 0.16) and moderate correlated paternity (rP = 0.20) in comparison to other eucalypt species. Despite significant differences in outcrossing rate and correlated paternity among populations, this variation was not correlated with fragmentation. Nevertheless, fragmentation was inversely correlated with the number of germinants per gram of seed capsule content. Outcrossing rate had been reported previously to decrease with increasing altitude in mainland populations of E. pauciflora, but this was not the case in Tasmania. However, a small but significant decrease in correlated paternity occurred with increasing altitude and a decrease in bi-parental inbreeding with increasing altitude was evident in fragmented populations only. It is argued that strong, but incomplete self-incompatibility mechanisms may buffer the mating system from changes in population density and pollinators. While seed yields from highly fragmented populations were reduced, in most cases the seed obtained is unlikely to be more inbred than that from non-fragmented populations and, thus, is likely to be as suitable for use in local forest restoration.

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Mixed Mating in Banksia brownii Baxter ex R. Br. (Proteaceae)

Australian Journal of Botany ◽

10.1071/bt9940103 ◽

1994 ◽

Vol 42 (1) ◽

pp. 103 ◽

Cited By ~ 13

Author(s):

JF Sampson ◽

BG Collins ◽

DJ Coates

Keyword(s):

Endangered Species ◽

Minimum Variance ◽

Outcrossing Rate ◽

Mixed Mating ◽

System Parameters ◽

Rare And Endangered Species ◽

Large Populations ◽

Rare And Endangered ◽

High Level ◽

Two Populations

Mating system parameters of the rare and endangered species Banksia brownii were estimated for two populations using both the mixed mating and effective selfing models. Estimates of outcrossing rate were similar in both populations for both models (mixed mating t Pop. 1=0.68, Pop. 2=0.75; effective selfing t Pop. 1=0.65, Pop. 2=0.73) and were among the lowest reported for undisturbed Banksia populations. Banksia brownii is killed by fire and the high level of selfing found may be associated with this trait. Multilocus and minimum variance mean i estimates were similar and the covariance of selfing with gene fixation (D) was not significantly different from zero indicating that populations were not structured and that most of the inbreeding was the result of self-fertilisation. The absence of structure was attributed to gene dispersal through pollen disperse by birds, and selection against inbred seed. It is suggested that several entire, large populations of this species together with habitat sufficient to support pollinators be reserved to conserve this species.

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Strongly deleterious mutations are a primary determinant of extinction risk due to inbreeding depression

10.1101/678524 ◽

2019 ◽

Cited By ~ 10

Author(s):

Christopher C. Kyriazis ◽

Robert K. Wayne ◽

Kirk E. Lohmueller

Keyword(s):

Genetic Diversity ◽

Inbreeding Depression ◽

Extinction Risk ◽

Fragmented Landscape ◽

Small Populations ◽

Deleterious Mutations ◽

Genetic Rescue ◽

Isolated Populations ◽

Large Populations ◽

Source Populations

AbstractHuman-driven habitat fragmentation and loss have led to a proliferation of small and isolated plant and animal populations with high risk of extinction. One of the main threats to extinction in these populations is inbreeding depression, which is primarily caused by the exposure of recessive deleterious mutations as homozygous by inbreeding. The typical approach for managing these populations is to maintain high genetic diversity, often by translocating individuals from large populations to initiate a ‘genetic rescue.’ However, the limitations of this approach have recently been highlighted by the demise of the gray wolf population on Isle Royale, which was driven to the brink of extinction soon after the arrival of a migrant from the large mainland wolf population. Here, we use a novel population genetic simulation framework to investigate the role of genetic diversity, deleterious variation, and demographic history in mediating extinction risk due to inbreeding depression in small populations. We show that, under realistic models of dominance, large populations harbor high levels of recessive strongly deleterious variation due to these mutations being hidden from selection in the heterozygous state. As a result, when large populations contract, they experience a substantially elevated risk of extinction after these strongly deleterious mutations are exposed by inbreeding. Moreover, we demonstrate that although translocating individuals to small populations is broadly effective as a means to reduce extinction risk, using small or moderate-sized source populations rather than large source populations can greatly increase the effectiveness of genetic rescue due to greater purging in these smaller populations. Our findings challenge the traditional conservation paradigm that focuses on maximizing genetic diversity to reduce extinction risk in favor of a view that emphasizes minimizing strongly deleterious variation. These insights have important implications for managing small and isolated populations in the increasingly fragmented landscape of the Anthropocene.Impact SummaryNumerous threats to extinction exist for small populations, including the detrimental effects of inbreeding. Although much of the focus in reducing these harmful effects in small populations has been on maintaining high genetic diversity, here we use simulations to demonstrate that emphasis should instead be placed on minimizing strongly deleterious variation. More specifically, we show that historically-large populations with high levels of genetic diversity also harbor elevated levels of recessive strongly deleterious mutations hidden in the heterozygous state. Thus, when these populations contract, inbreeding can expose these strongly deleterious mutations as homozygous and lead to severe inbreeding depression and rapid extinction. Moreover, we demonstrate that, although translocating individuals to these small populations to perform a ‘genetic rescue’ is broadly beneficial, the effectiveness of this strategy can be greatly increased by targeting historically-smaller source populations where recessive strongly deleterious mutations have been purged. These results challenge long-standing views on how to best conserve small and isolated populations facing the threat of inbreeding depression, and have immediate implications for preserving biodiversity in the increasingly fragmented landscape of the Anthropocene.

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Population size, habitat fragmentation, and the nature of adaptive variation in a stream fish

Proceedings of The Royal Society B Biological Sciences ◽

10.1098/rspb.2014.0370 ◽

2014 ◽

Vol 281 (1790) ◽

pp. 20140370 ◽

Cited By ~ 31

Author(s):

Dylan J. Fraser ◽

Paul V. Debes ◽

Louis Bernatchez ◽

Jeffrey A. Hutchings

Keyword(s):

Genetic Variation ◽

Habitat Fragmentation ◽

Population Size ◽

Brook Trout ◽

Small Populations ◽

Adaptive Genetic Variation ◽

Genetic Population ◽

Fragmented Populations ◽

Large Populations ◽

Adaptive Differentiation

Whether and how habitat fragmentation and population size jointly affect adaptive genetic variation and adaptive population differentiation are largely unexplored. Owing to pronounced genetic drift, small, fragmented populations are thought to exhibit reduced adaptive genetic variation relative to large populations. Yet fragmentation is known to increase variability within and among habitats as population size decreases. Such variability might instead favour the maintenance of adaptive polymorphisms and/or generate more variability in adaptive differentiation at smaller population size. We investigated these alternative hypotheses by analysing coding-gene, single-nucleotide polymorphisms associated with different biological functions in fragmented brook trout populations of variable sizes. Putative adaptive differentiation was greater between small and large populations or among small populations than among large populations. These trends were stronger for genetic population size measures than demographic ones and were present despite pronounced drift in small populations. Our results suggest that fragmentation affects natural selection and that the changes elicited in the adaptive genetic composition and differentiation of fragmented populations vary with population size. By generating more variable evolutionary responses, the alteration of selective pressures during habitat fragmentation may affect future population persistence independently of, and perhaps long before, the effects of demographic and genetic stochasticity are manifest.

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Costs and benefits of the mixed-mating system of Narcissus serotinus (Amaryllidaceae) in the conservation of small fragmented populations

Botany ◽

10.1139/cjb-2013-0197 ◽

2014 ◽

Vol 92 (2) ◽

pp. 113-122 ◽

Cited By ~ 3

Author(s):

Isabel Marques ◽

David Draper ◽

José María Iriondo

Keyword(s):

Inbreeding Depression ◽

Floral Biology ◽

Mixed Mating ◽

Reproductive Assurance ◽

Evolutionary Potential ◽

Mixed Mating System ◽

Fragmented Populations ◽

Large Populations ◽

Fruit And Seed Set ◽

Plant Pollinator

Small fragmented populations often exhibit reduced plant–pollinator interactions and scarce outcrossing opportunities. In this context, mixed-mating systems can be advantageous since selfing can provide reproductive assurance, but they may also carry relevant costs such as those involved in inbreeding depression. This study examines the advantages and costs of selfing in Narcissus serotinus L., a mixed-mating geophyte that currently occurs in several fragmented populations in Portugal, that resulted from the construction of the largest European dam. Observation of pollinators revealed that cross-pollination is less frequent in small than in large populations. Manual self-pollinations significantly increased fruit and seed set in small-size populations, also suggesting limited insect pollination. The existence of selfing may provide reproductive assurance in small-size populations of N. serotinus where outcrossing pollination is reduced. Although floral biology and experimental pollinations showed that N. serotinus is capable of autonomous selfing, four of the six fitness traits studied showed significant inbreeding depression in all populations. The high levels of inbreeding depression found in N. serotinus suggest that the initial reproductive assurance advantage of selfing may be counterbalanced by lower survival of the resulting individuals and a decrease in the evolutionary potential of the populations.

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Mating system of Calluna vulgaris: self-sterility and outcrossing estimations

Canadian Journal of Botany ◽

10.1139/b97-148 ◽

1998 ◽

Vol 76 (1) ◽

pp. 37-42 ◽

Cited By ~ 3

Author(s):

Grégory Mahy ◽

Anne-Laure Jacquemart

Keyword(s):

Mating System ◽

Inbreeding Depression ◽

Calluna Vulgaris ◽

Pollen Tubes ◽

Outcrossing Rate ◽

Evolutionary Significance ◽

Mixed Mating ◽

Mixed Mating System ◽

Cross Pollination ◽

Mating System Evolution

The evolutionary significance of a mixed mating system is currently under debate. Calluna vulgaris (L). Hull, a widespread European shrub, is likely to undergo mixed mating because of geitonogamy. Mating system was investigated in three populations of C. vulgaris by means of greenhouse controlled crosses, pollen tube observations, and outcrossing rate estimations from allozyme markers. The species is highly self-sterile, most probably as a result of early inbreeding depression. Mean fruit set and mean seed number per fruit following hand self-pollination were 48 and 13%, respectively, of those following cross-pollination. Pollen tubes produced by self pollen penetrated the ovary with the same success as those from cross-pollination. Multilocus estimates of the outcrossing rates ranged from 0.71 to 0.90, and two estimates were significantly different from 1.00. Calluna vulgaris could thus be classified as being mixed mating with predominant allogamy. Single-locus estimates did not differ significantly from multilocus estimates suggesting that biparental inbreeding did not contribute to the apparent selfing rate. The maintenance of high early inbreeding depression despite an intermediate level of selfing is discussed with respect to recent theories on mating system evolution. Key words: Calluna vulgaris, mating system, self-sterility, pollen tubes, outcrossing rate, inbreeding depression.

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Estimation of Mating System in the Endangered Aquatic Fern Ceratopteris pteridoides in China Based on AFLP Molecular Marker and Selfing Test: Implications for Conservation

Notulae Botanicae Horti Agrobotanici Cluj-Napoca ◽

10.15835/nbha46211144 ◽

2018 ◽

Vol 46 (2) ◽

pp. 688-699 ◽

Cited By ~ 1

Author(s):

Xiang DONG ◽

Hong LIU ◽

Wei GAO ◽

Rui QIN ◽

Andrew W. GICHIRA ◽

...

Keyword(s):

Mating System ◽

Clonal Growth ◽

Vegetative Reproduction ◽

Mean Value ◽

Outcrossing Rate ◽

Species Level ◽

Ex Situ ◽

Aquatic Fern ◽

Threatened And Endangered Species ◽

High Level

Mating system has important implications for the genetic structure and diversity of populations, especially threatened and endangered species. In this study, mating system of the endangered aquatic fern Ceratopteris pteridoides in China was investigated using AFLP markers and selfing test. The results of AFLP analyses showed that the estimate of multilocus outcrossing rate (tm) was high at species level (tm = 0.999), indicating that C. pteridoides is a predominant outcrossing species. The small differences between tm and ts (0.136 ± 0.003) at species level showed that there is a low tendency for mating between relatives. The selfing test showed that isolated gametophytes formed the rate of normal sporophytes in three populations (BLH, ZDH, WCH) ranging from 72.9% to 77.8% with a mean value of 75.2%, indicating that C. pteridoides has a high level of intragametophytic selfing potential. Our investigation found that some of the studied populations of C. pteridoides have a prolific capacity for vegetative reproduction (clonal growth). The results revealed that the diploid homosporous pteridophyte C. pteridoides predominantly favors gametophytic crossing with a certain level of inbreeding along with clonal growth. We suggest that mating system of C. pteridoides may be adjusted to promote selfing rate in response to factors including the characteristics of hermaphrodite, and colonization events and small extant populations. As a result of the high outcrossing rate of C. pteridoides, we recommend that ex situ plantings would be most suitable for enhancing possible intermingling of the different populations thus minimizing inbreeding.

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Genomic insights into the conservation status of the world’s last remaining Sumatran rhinoceros populations

Nature Communications ◽

10.1038/s41467-021-22386-8 ◽

2021 ◽

Vol 12 (1) ◽

Author(s):

Johanna von Seth ◽

Nicolas Dussex ◽

David Díez-del-Molino ◽

Tom van der Valk ◽

Verena E. Kutschera ◽

...

Keyword(s):

Inbreeding Depression ◽

Conservation Status ◽

Small Population ◽

Small Populations ◽

Mutational Load ◽

Malay Peninsula ◽

Isolated Populations ◽

Risk Of Extinction ◽

Population Sizes ◽

Near Future

AbstractSmall populations are often exposed to high inbreeding and mutational load that can increase the risk of extinction. The Sumatran rhinoceros was widespread in Southeast Asia, but is now restricted to small and isolated populations on Sumatra and Borneo, and most likely extinct on the Malay Peninsula. Here, we analyse 5 historical and 16 modern genomes from these populations to investigate the genomic consequences of the recent decline, such as increased inbreeding and mutational load. We find that the Malay Peninsula population experienced increased inbreeding shortly before extirpation, which possibly was accompanied by purging. The populations on Sumatra and Borneo instead show low inbreeding, but high mutational load. The currently small population sizes may thus in the near future lead to inbreeding depression. Moreover, we find little evidence for differences in local adaptation among populations, suggesting that future inbreeding depression could potentially be mitigated by assisted gene flow among populations.

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Spatial structure and inbreeding depression in slickspot peppergrass, Lepidium papilliferum (Brassicaceae)

Botany ◽

10.1139/b08-053 ◽

2008 ◽

Vol 86 (9) ◽

pp. 1002-1008 ◽

Cited By ~ 2

Author(s):

Stephanie A. Billinge ◽

Ian C. Robertson

Keyword(s):

Spatial Structure ◽

Inbreeding Depression ◽

Reproductive Performance ◽

Fruit Set ◽

Leaf Length ◽

Small Populations ◽

Hand Pollination ◽

Large Populations ◽

Pollen And Seed Dispersal ◽

Close Relatives

In plants with limited pollen and seed dispersal, populations are often spatially structured such that neighboring individuals are more closely related to one another than to distant individuals. Mating among close relatives, including selfing, may lead to a reduction in reproductive performance through the effects of prezygotic mating barriers and inbreeding depression. Studying 11 populations of slickspot peppergrass, Lepidium papilliferum (L.F. Hend.) A. Nels. and J.F. Macbr (Brassicaceae), a rare mustard endemic to southwestern Idaho, we investigated whether small populations (16–746 flowering individuals) exhibit spatial structure as previously reported for large populations (>3000 flowering individuals). Through hand-pollination experiments we found that percent fruit set increased with increasing distance between parents up to a distance of 3 m, and declined slightly but nonsignificantly at greater outcrossing distances. Self-pollinated plants produced little or no fruit. Germination of seeds from the hand-pollination experiment revealed signs of inbreeding depression in the offspring. Specifically, leaf length of developing seedlings increased significantly as a function of outcrossing distance. Total leaf number showed a similar, yet statistically nonsignificant, response to outcrossing distance. Overall, our experiments reveal spatial structuring and suggest the occurrence of inbreeding depression in small populations of L. papilliferum.

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The mating system in natural populations of Thujaorientalis

Canadian Journal of Forest Research ◽

10.1139/x91-041 ◽

1991 ◽

Vol 21 (3) ◽

pp. 333-339 ◽

Cited By ~ 10

Author(s):

Chang Yi Xie ◽

Bruce P. Dancik ◽

Francis C. Yeh

Keyword(s):

Mating System ◽

Expectation Maximization ◽

Natural Populations ◽

Expectation Maximization Algorithm ◽

Outcrossing Rate ◽

Significant Heterogeneity ◽

System Parameters ◽

Marker Loci ◽

Self Fertilization ◽

The Mean

EM (expectation–maximization) algorithm procedures were used to estimate mating-system parameters in four natural populations of Thujaorientalis L. from China using seven allozyme marker loci (Fest1, Idh1, Idh2, Mr, Pgi2, Skdh1, and 6Pg2). The mean single-locus outcrossing rate was 0.70 for the species, but estimates showed that there was significant heterogeneity among loci within populations. Multilocus estimates of the outcrossing rate showed that there was significant heterogeneity among populations and among trees within populations. The mean multilocus outcrossing rate (0.75) was higher than the outcrossing rate (0.63) observed in a closely related conifer, Thujaoccidentalis L., but lower than estimates that have been reported for most other conifers. Significant heterozygote deficiencies, relative to Hardy–Weinberg and mating-system equilibria, were observed in all filial populations. In contrast, the maternal populations conformed to Hardy–Weinberg and mating-system equilibria at most loci. Self-fertilization and other forms of inbreeding (e.g., sibling mating) within the sampled populations are important contributors to the low outcrossing estimates in this conifer.

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