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Genetic diversity in clustered colonies of an Antarctic marine mesopredator: a role for habitat quality?

Published online by Cambridge University Press:  31 March 2021

Emiliano Mori
Affiliation:
Department of Life Sciences, University of Siena, Via P.A. Mattioli 4, 53100Siena, Italy Consiglio Nazionale delle Ricerche - Istituto di Ricerca sugli Ecosistemi Terrestri - Via Madonna del Piano 10, 50019, Sesto Fiorentino, Italy
Claudia Brunetti
Affiliation:
Department of Life Sciences, University of Siena, Via Aldo Moro 2, 53100Siena, Italy
Antonio Carapelli
Affiliation:
Department of Life Sciences, University of Siena, Via Aldo Moro 2, 53100Siena, Italy
Lucia Burrini
Affiliation:
Department of Life Sciences, University of Siena, Via P.A. Mattioli 4, 53100Siena, Italy
Niccolò Fattorini
Affiliation:
Department of Life Sciences, University of Siena, Via P.A. Mattioli 4, 53100Siena, Italy
Francesco Ferretti
Affiliation:
Department of Life Sciences, University of Siena, Via P.A. Mattioli 4, 53100Siena, Italy
Silvia Olmastroni*
Affiliation:
Department of Physical, Earth and Environmental Sciences, University of Siena, Via P.A. Mattioli 4, 53100Siena, Italy Museo Nazionale dell'Antartide ‘F. Ippolito’, Sede di Siena, Via Laterina 8, 53100Siena, Italy
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Abstract

Genetic structure may be highly variable across seabird species, and particularly among those that are distributed over large geographical areas. The Adélie penguin (Pygoscelis adeliae) is a numerically dominant Antarctic seabird that is considered to be a key species in coastal ecosystems. Since the Last Glacial Maximum, penguin colonization of the Antarctic coastline occurred at varying geographical and temporal scales, contributing to an incomplete understanding of how modern colonies relate to each other at local or regional scales. We assessed the population genetic structure of Adélie penguins (n = 86 individuals) from three adjacent colonies along the Victoria Land coast using molecular genetic markers (i.e. seven microsatellite loci isolated through next-generation sequencing). Our results indicate meta-population dynamics and possibly relationships with habitat quality. A generally low genetic diversity (Nei's index: 0.322–0.667) was observed within each colony, in contrast to significant genetic heterogeneity among colonies (pairwise FST = 0.071–0.148), indicating that populations were genetically structured. Accordingly, an assignment test correctly placed individuals within the respective colonies from which they were sampled. The presence of inter-colony genetic differentiation contrasts with previous studies on this species that showed a lack of genetic structure, possibly due to higher juvenile or adult dispersal. Our sampled colonies were not panmictic and suggest a lower migration rate, which may reflect relatively stable environmental conditions in the Ross Sea compared to other regions of Antarctica, where the ocean climate is warming.

Type
Biological Sciences
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s), 2021. Published by Cambridge University Press

Introduction

Ocean currents and oceanographic barriers may influence the dispersal behaviour of marine predators, therefore affecting gene flow and facilitating biogeographical breaks among populations (Vianna et al. Reference Vianna, Noll, Dantas, Petry, Barbosa and González-Acuña2017). Natal philopatry may play a major role in shaping population demographics and the genetic structure of marine seabirds (Milot et al. Reference Milot, Weimerskirch and Bernatchez2008). Return to natal localities may have several advantages (e.g. population ‘knowledge’ about food resources and predators), but the occurrence of philopatry can be influenced by the degree of environmental variability or population pressures (Coulson Reference Coulson2016).

Given its geographical isolation including regional oceanographic barriers, populations of Antarctic organisms may be locally adapted and therefore show genetic structuring (Vianna et al. Reference Vianna, Noll, Dantas, Petry, Barbosa and González-Acuña2017). The Antarctic Polar Front and the Antarctic Circumpolar Current are major driving forces that influence species distribution, serving as barriers or facilitators to animal movements in both north-south and clockwise directions, respectively (Vianna et al. Reference Vianna, Noll, Dantas, Petry, Barbosa and González-Acuña2017). Vertebrate distribution and colonization of Antarctica have been shaped by cycles of glacial and interglacial periods (Cole et al. Reference Cole, Dutoit, Dussex, Hart, Alexander and Younger2019). During the Holocene (the last 10 kya), the distribution and occupancy rates of marine bird and mammal species sensitive to changes in coastal glacial and sea-ice conditions have been influenced by ice-sheet advances and retreats, as well as by pack-ice cover, fast ice and polynya extension (Mezgec et al. Reference Mezgec, Stenni, Crosta, Masson-Delmotte, Baroni and Braida2017). For instance, populations of the Adélie penguin (Pygoscelis adeliae) are circumpolar and exhibit two distinct and divergent mitochondrial lineages (A, ‘Antarctica’ and RS, 'Ross Sea') (Roeder et al. Reference Roeder, Marshall, Mitchelson, Visagathilagar, Ritchie and Love2001). Modern populations inhabiting Victoria Land in the Ross Sea present a mixture of both lineages, with frequencies of the Ross Sea ‘RS’ lineage increasing with increasing latitudes (Ritchie et al. Reference Ritchie, Millar, Gibb, Baroni and Lambert2004, Younger et al. Reference Younger, Emmerson, Southwell, Lelliott and Miller2015). Thus, different colonization patterns may have occurred at differing geographical and temporal scales (Emslie et al. Reference Emslie, Coats and Licht2007). In this region, penguin occupation occurred after ice sheets retreated following the Last Glacial Maximum (i.e. when the open sea and the ice-free land became available to the Adélie penguin for foraging and breeding) (Ainley Reference Ainley2002, Emslie et al. Reference Emslie, Coats and Licht2007). Deposits of subfossil bones and eggshells reveal that the species inhabited central Victoria Land since 8000 bp, but at different temporal and geographical scales (Emslie et al. Reference Emslie, Coats and Licht2007). During this period, gene frequencies have changed at the population level (Shepherd et al. Reference Shepherd, Millar, Ballard, Ainley, Wilson and Haynes2005). Shepherd et al. (Reference Shepherd, Millar, Ballard, Ainley, Wilson and Haynes2005) concluded that micro-evolutionary changes among modern Adélie penguin populations may have been promoted by altered dispersal as a consequence of stochastic events creating physical barriers, such as mega-icebergs.

Genetic structure may be highly variable across many seabird species, and particularly among penguins living in different geographical areas (Clucas et al. Reference Clucas, Dunn, Dyke, Emslie, Levy and Naveen2014, Gorman et al. Reference Gorman, Talbot, Sonsthagen, Sage, Gravely, Fraser and Williams2017). According to more recent studies, however, gene flow among pygoscelid colonies should be low and population genetic structure should be expected (for strongly philopatric species, see Ainley Reference Ainley2002, Vianna et al. Reference Vianna, Noll, Dantas, Petry, Barbosa and González-Acuña2017). On the other hand, a lack of genetic structure has been described for penguin species living at more northern latitudes (Clucas et al. Reference Clucas, Dunn, Dyke, Emslie, Levy and Naveen2014, Gorman et al. Reference Gorman, Talbot, Sonsthagen, Sage, Gravely, Fraser and Williams2017, Cole et al. Reference Cole, Dutoit, Dussex, Hart, Alexander and Younger2019). Similarly, Roeder et al. (Reference Roeder, Marshall, Mitchelson, Visagathilagar, Ritchie and Love2001), using six polymorphic microsatellite loci, detected no genetic differentiation among colonies of Adélie penguins throughout the Antarctic continent. Those findings have been confirmed both by Clucas et al. (Reference Clucas, Dunn, Dyke, Emslie, Levy and Naveen2014) and by Gorman et al. (Reference Gorman, Talbot, Sonsthagen, Sage, Gravely, Fraser and Williams2017), who focused on colonies of the western Antarctic Peninsula.

Central place foragers such as penguins breed in colonies, and their distribution in the Antarctic varies according to density-dependent regulation, affected by the quality of the marine and terrestrial habitat (i.e. the presence of polynya and submarine canyons and the availability of terrestrial ice-free habitat) (Southwell & Emmerson Reference Southwell and Emmerson2020, Santora et al. Reference Santora, LaRue and Ainley2020). Among Antarctic penguins, the Adélie penguin is a highly abundant sea ice-obligate species and as such it is considered as a key indicator species for both land and ocean environments (cf. Ainley Reference Ainley2002). The Adélie penguin winters in the pack ice surrounding the continent, subject to large-scale ice movement (e.g. Ballard et al. Reference Ballard, Toniolo, Ainley, Parkinson, Arrigo and Trathan2010), and, during spring, individuals reach ice- and snow-free sites along the coast to occupy breeding colonies (Ainley Reference Ainley2002, Lynch & LaRue Reference Lynch and LaRue2014). During the breeding season, from October to February, 31 discrete colonies occur along the Victoria Land shoreline and together contribute ~33% of the total global population (Lynch & LaRue Reference Lynch and LaRue2014). The colonies occur in clusters, associated with polynyas, with smaller ones neighbouring a large colony (Ainley Reference Ainley2002, Santora et al. Reference Santora, LaRue and Ainley2020).

The Adélie penguin is philopatric (i.e. it shows high nest and colony fidelity, as well as minimal juvenile dispersal) (Ainley Reference Ainley2002, Dugger et al. Reference Dugger, Ainley, Lyver, Barton and Ballard2010), and as a consequence, a low level of gene flow is expected between populations (Nei Reference Nei1987). Nevertheless, the dynamics of contemporary populations are pivotal in understanding population fluctuations of this species in a changing environment (LaRue et al. Reference LaRue, Ainley, Swanson, Dugger, Lyver, Barton and Ballard2013, Dugger et al. Reference Dugger, Ballard, Ainley, Lyver and Schine2014). How colonies occurring in a common geographical area relate to each other, or with much more distant colonies, is still little understood, although dispersal can affect population dynamics at the regional scale. Neighbouring colonies, not isolated but spatially separated, may interact as a meta-population (i.e. an assemblage of spatially delimited local populations that are coupled by some degree of migration) (Hanski & Gaggiotti Reference Hanski and Gaggiotti2004). Molecular genetic markers, particularly microsatellite loci, have increased our understanding of the demographic history and phylogenetic relationships of penguin species (Roeder et al. Reference Roeder, Marshall, Mitchelson, Visagathilagar, Ritchie and Love2001, Gorman et al. Reference Gorman, Talbot, Sonsthagen, Sage, Gravely, Fraser and Williams2017, Vianna et al. Reference Vianna, Noll, Dantas, Petry, Barbosa and González-Acuña2017).

Here, using microsatellite loci previously isolated through next-generation sequencing (Roeder et al. Reference Roeder, Marshall, Mitchelson, Visagathilagar, Ritchie and Love2001, Shepherd et al. Reference Shepherd, Millar, Ballard, Ainley, Wilson and Haynes2005, Gorman et al. Reference Gorman, Talbot, Sonsthagen, Sage, Gravely, Fraser and Williams2017), we assessed the small-scale population genetic structure of Adélie penguins from three adjacent colonies situated along the central Victoria Land coast. Inter-colony dynamics through population genetics have never been analysed among these colonies. We discuss our results in the context of meta-population dynamics (Hanski & Gaggiotti Reference Hanski and Gaggiotti2004, Bicknell et al. Reference Bicknell, Knight, Bilton, Campbell, Reid, Newton and Votier2014) considering colony size, habitat quality and possible environmental forcing and evolutionary biology.

Material and methods

Study area

Our study took place from 10 November 2017 to 7 February 2018 in a cluster of three colonies occurring between Wood Bay and Terra Nova Bay (TNB), in a 75 km stretch of coast along central Victoria Land, Ross Sea (Antarctica) (Fig. 1): Inexpressible Island (74°54'S, 163°39'E), Adélie Cove (74°46'S, 164°00'E) and Edmonson Point (74°20'S, 165°08'E). The cluster is isolated, with the closest colonies ~200 km from one another (south-east: Franklin Island; north: Coulman Island) (Fig. 1).

Fig. 1. Map of the Victoria Land coast and location of the three colonies. Location of the Italian research station MZS is also shown. Landsat image from Qantarctica3 (https://www.npolar.no/quantarctica), LIMA Landsat image mosaic of Antarctica (15/240 m) USGS/Remote Sensing of Environment, 2008. MZS = Mario Zucchelli Station; TNB = Terra Nova Bay.

Marine habitat

The TNB area has a unique marine fauna and shows high diversity at both the species and community levels (Povero et al. Reference Povero, Castellano, Ruggieri, Monticelli, Saagiomo and Mariachiara Chiantore2004). Oceanographic characteristics are dominated by the presence of the ‘latent heat’ TNB polynya, where strong and persistent katabatic winds drive newly formed sea ice offshore. Here, high primary production and strong benthic-pelagic coupling support species- and biomass-rich benthic and water-column communities (Davis et al. Reference Davis, Hofmann, Klinck, Piñones and Dinniman2017). The Drygalski Ice Tongue plays an important role as a regulator of the size of the TNB polynya (Mezgec et al. Reference Mezgec, Stenni, Crosta, Masson-Delmotte, Baroni and Braida2017). Accordingly, the TNB area is a hotspot and a nursery area for the pelagic silverfish (Pleuragramma antarctica), a key species in the coastal food web, also supporting abundant crystal krill (Euphausia crystallorophias) stocks (Davis et al. Reference Davis, Hofmann, Klinck, Piñones and Dinniman2017). Accordingly, the TNB area contains several colonies of Adélie penguin, Emperor penguin (Aptenodytes forsteri), south polar skua (Stercorarius maccormicki) and other flying seabirds (Harris et al. Reference Harris, Lorenz, Fishpool, Lascelles, Cooper and Coria2015) and marine mammals (e.g. seals and cetaceans: Lauriano et al. Reference Lauriano, Fortuna and Vacchi2011, LaRue et al. Reference LaRue, Salas, Nur, Ainley, Stammerjohn and Barrington2019).

Colony habitat

The Adélie penguin colony at Inexpressible Island occupies ice-free ground on the eastern shore, where terrain is relatively flat, with a ridge of ~110 m above sea level (a.s.l.) elevation along the western flank. The area is strongly affected by katabatic winds flowing down a glacial valley towards the sea. The breeding population size in 2013 was 36,117 pairs (P.O.B. Lyver, personal observation 2013, Adélie census data, unpublished dataset, www.penguinmap.com) (Table I).

Table I. Ecological features of the three colonies located in central Victoria Land, Ross Sea, Antarctica. The linear distance to Terra Nova Bay polynya and range of fast-ice extension were measured using EOSDIS Worldview (https://worldview.earthdata.nasa.gov) to the best image available in late October, mid-December and mid-January from 2000 to 2018. The approximate size of colony area was measured with Google Earth Pro on images 23 February 2010, 27 November 2011 and 2 December 2011 for Edmonson Point, Adélie Cove and Inexpressible Island, respectively.

a Data from ground census of 29 November 2017, this study.

b Data from ground census (December 2017: S. Olmastroni, unpublished data 2017).

c Data for December 2013 from http://www.penguinmap.com/mapppd.

To the north, 17 km away, is the colony at Adélie Cove, a small 70 m-deep bay. The colony is located on a steep slope (80 m a.s.l.) and nests are distributed on ridges. The area is affected by katabatic winds. The breeding populations size in 2013 was 13,408 pairs (P.O.B. Lyver, personal observation 2013, Adélie census data, unpublished dataset, www.penguinmap.com) (Table I). Further north, 75 km from Inexpressible Island, is the colony at Edmonson Point, in a small ice-free area (1.79 km2) in Wood Bay. The colony consists of two main groups of nests located 600 m apart, the larger on a beach and the smaller on a volcanic terrace with a mild slope (25 m a.s.l.). The area is generally not affected by katabatic winds, and thus possesses several kilometres of fast ice that remains in place until late February. The breeding population size in 2017 was 2704 pairs (S. Olmastroni, unpublished data 2017). Terrestrial predators (i.e. south polar skuas) occur at each colony (Table I), as do marine predators (i.e. Leopard seals Hydrurga leptonyx) at adjacent beaches. Killer whales (Orcinus orca, ecotype B) have been observed travelling along the fast-ice edge and shoreline among the Wood Bay and TNB area (Lauriano et al. Reference Lauriano, Fortuna and Vacchi2011). A previous study showed that the penguins fed little inside the TNB polynya area, but rather used it to reach the pack ice that rings the polynya, rather than to walking (Olmastroni et al. Reference Olmastroni, Fattorini, Pezzo and Focardi2020).

Data collection

At the beginning of the breeding season (early November), a total of 50 occupied nests were selected in each colony for carrying out different research activities in the framework of the PenguinERA project (PNRA2016 AZ1.11) and for the long-term monitoring of the Adélie penguins in the TNB area (cf. Olmastroni et al. Reference Olmastroni, Fattorini, Pezzo and Focardi2020). An Adélie penguin colony is composed of numerous separated subgroups of different sizes and shapes (Ainley Reference Ainley2002); therefore, we attempted to balance sampling spatially. In particular, both peripheral and central breeders (see Tenaza Reference Tenaza1971) in different subgroups within each colony were selected to limit differences in nest characteristics (e.g. nesting success and colony growth) and to maximize distance among individuals (i.e. to avoid inbreeding and relatedness) (cf. Cristofari et al. Reference Cristofari, Trucchi, Whittington, Vigetta, Gachot-Neveu and Stenseth2015). As our study was carried out throughout the breeding period, no central nests located beyond three nests from the colony edge were sampled in order to limit disturbance to the other breeders. Up to six feathers per individual were plucked from the chest area. To reduce stress of capturing and handling, adult penguins were gently lifted from their nests and covered with a hood, while eggs and/or chicks were protected and kept warm during handling. Penguins were marked with passive transponders (TIRIS™ Texas Instruments Registration and Identification System) and externally with a temporary dye to avoid recapturing the same individual. We released each penguin in front of its nest after a 10 min maximum holding time and observed individuals until they returned to their regular breeding activity. Feather samples for this study were collected from 30 adult penguins per colony within the 50 relevant previously marked nests and stored in sealed plastic bags at -20°C until genetic analysis was conducted.

DNA extraction, amplification and sequencing

Two feathers per individual were used for DNA extraction. The total genome DNA was extracted successfully from 26–32 individuals per colony (Edmonson Point, n = 28; Adélie Cove, n = 32; Inexpressible Island, n = 26) through the QIAamp DNA Micro Kit (©Qiagen 2013–18) following the Isolation from Tissues Protocol. Analyses were then normalized for the smallest sample. The DNA content was quantified with a NanoDrop ND1000UV (©NanoDrop Technologies) then stored at 4°C. Polymerase chain reactions (PCRs) were carried out for seven microsatellite loci (Table II) widely used in previous studies, so as to allow comparison with other works on the same species (Roeder et al. Reference Roeder, Marshall, Mitchelson, Visagathilagar, Ritchie and Love2001, Shepherd et al. Reference Shepherd, Millar, Ballard, Ainley, Wilson and Haynes2005, Gorman et al. Reference Gorman, Talbot, Sonsthagen, Sage, Gravely, Fraser and Williams2017). The PCRs were run in a total volume of 25 μl containing at least 2 μl of DNA at 20 ng/μl, 0.4 μM of each primer, 200 μM of each dNTP, 1.5 mM of MgCl2, 1× reaction buffer and 0.125 μl of GoTaq Flexi DNA Polymerase (5 units/μl) (©Promega).

Table II. Characterization of microsatellite loci of Adélie penguins used in our work.

After the electrophoretic run on 1.5% agarose gel, a solution containing 1 μl of PCR product was prepared for each amplified DNA diluted with sterile distilled water in an amount proportional to the intensity of the band, containing 13.5 μl of deionized formamide (denaturing agent; ©AppliChem) and 0.3 μl of a size standard (ROX 500 size standard; ©Applied Biosystems). Then, we proceeded with a denaturation step of 10 min at 94°C. Samples were run using an automatic multicapillary sequencer (ABI Prism 373, ©Applied Biosystems) at the Department of Life Sciences of the University of Siena. The software Geneious 6.0.3 (Kearse et al. Reference Kearse, Moir, Wilson, Stones-Havas, Cheung and Sturrock2012) was used to establish the precise assignment of amplified allelic sizes. The obtained results were displayed on a two-dimensional graph, with the abscissa corresponding to the length (bp) and the ordinate to the peak height (fluorescence unit). The height of the peaks, the intensity of which being proportional to the amount amplified, has the same meaning as the intensity of the electrophoresis band on agarose gel. The allelic range was calculated for each locus on the basis of the maximum and minimum lengths found for the analysed samples.

Statistical analyses of the microsatellite data

We assessed whether null alleles (i.e. non-amplified), allelic dropouts and errors due to stutter peaks occurred, and the polymorphic informative content (PIC) was also assessed using standard methods (see Supplementary Material). We computed allelic richness (i.e. the number of alleles per locus corrected per sample size), allelic frequencies and private alleles (i.e. those occurring only in one colony and not detected in the others), Nei's genetic diversity index and the values of the F ST parameter according to Wright's F-statistics (i.e. the measure of genetic differentiation among colonies). Deviations from the Hardy-Weinberg equilibrium (HWE) and from linkage disequilibrium (LE) were also calculated for each locus and for the total loci per colony. The significance level for the HWE and LE was estimated using a Bonferroni correction. We estimated gene flow, expressed as the number of migrants among colonies per generation, corrected for population size (i.e. the average number of migrants successfully entering each population per generation). To conclude, we performed a cluster analysis on the microsatellite (short tandem repeat, STR) genotypic profile of each individual using the Bayesian method (Supplementary Material). The probability that each individual belonged to each of the clusters defined by the program was calculated (Supplementary Material).

Results

Six of the seven microsatellite loci chosen for this study were successfully amplified in all samples. The high number of non-specific bands (i.e. 4–6) obtained in the electrophoretic run of the locus TP500, despite all precautions applied (i.e. addition of dimethyl sulfoxide in PCR, alteration of the concentration of MgCl2, increases in the annealing temperature; see Roeder et al. Reference Roeder, Marshall, Mitchelson, Visagathilagar, Ritchie and Love2001), made the locus almost useless. Several samples sequenced for this locus (TP500), considering its length based on published data (Roeder et al. Reference Roeder, Marshall, Mitchelson, Visagathilagar, Ritchie and Love2001, Shepherd et al. Reference Shepherd, Millar, Ballard, Ainley, Wilson and Haynes2005), were monomorphic in the three study colonies (PIC = 0). Therefore, the TP500 locus was excluded from further analysis.

Analyses carried out with MicroChecker did not show any evidence of stutter bands, nor allelic dropout. Amplified loci showed a medium to high PIC values (Table III). The majority of the unique alleles (i.e. characteristic of a population) were found for the largest colony (i.e. Inexpressible Island; n = 6). Consistently, the lowest number of private alleles (n = 1) was observed at Edmonson Point (Fig. 2).

Fig. 2. Allelic frequencies for each locus for all studied colonies: arrows on the x-axis show private alleles.

Table III. Polymorphic informative content (PIC) and allelic richness for each locus and for each colony, corrected for population size.

The allelic richness corrected for the population size reached a maximum in all comparisons for the XVCII locus (up to 9.9). At the population level, the lowest values were observed for Edmonson Point (range: 1.9–3.0) and the highest values were observed for Inexpressible Island (range: 4.0–8.0), apart from the locus XVCII in Adélie Cove (allelic richness: 9.9) (Table III). The three-dimensional factorial correspondence analysis showed the presence of three well-defined clusters (permutation test of θ using 1000 re-samplings = 0.095–0.224, P < 0.01 in all pairwise comparisons) (Fig. 3). Our study colonies showed no significant deviation from the HWE (all P < 0.005) (Table IV). Pairwise comparisons of all loci assessed by a drop-down menu of the software Genepop showed no LD for population genetics analysis. Therefore, the association of alleles in different loci in the investigated colonies was random. The F ST values (Table V) were significant (all P < 0.05), with the highest value found in the comparison between the largest and the smallest colonies (i.e. Inexpressible Island and Edmonson Point, respectively) (Table V). Nei's diversity index confirmed that the highest value of genetic diversity was found for the Inexpressible Island colony (0.67 ± 0.22) (Table V).

Fig. 3. Tridimensional factorial correspondence analysis, including all of the sampled individuals (yellow = Adélie Cove; red = Inexpressible Island; blue = Edmonson Point). Axes show the variables explaining the variability of the genetic diversity in our dataset.

Table IV. Hardy-Weinberg equilibrium multilocus test and tests for deficiency and excess of heterozygotes.

Table V. Results of the analysis of molecular variance between colonies (F ST) and Nei's diversity indices for genetic diversity (average gene diversity ± standard deviation).

Gene flow between colonies is limited to four emigrating individuals every three generations (number of emigrating individuals corrected for population size = 1.33 per generation over the sampled population), thus showing isolation among populations. The Bayesian analysis of the genotyping of the three colonies confirmed a subdivision into three clusters (Fig. 4); ΔK (i.e. an ad hoc quantity based on the second-order change rate of the likelihood function with respect to K) was the highest for K = 3.

Fig. 4. Probabilities of assignment of Adélie penguin individuals to putative population clusters following the Bayesian analysis of population structure for six microsatellite loci per individual. Each individual penguin is represented by vertical lines and different colours represent different clusters (blue = Edmonson Point; yellow = Adélie Cove; red = Inexpressible Island). The structure plot was obtained without prior location information.

Discussion

In our work, microsatellite data revealed limited dispersal in Adélie penguins among an isolated cluster of three adjacent colonies in Victoria Land. A significant level of population genetic structure was detected, greater than what has been observed among other colonies of this species using polymorphic markers (Roeder et al. Reference Roeder, Marshall, Mitchelson, Visagathilagar, Ritchie and Love2001, Gorman et al. Reference Gorman, Talbot, Sonsthagen, Sage, Gravely, Fraser and Williams2017). The F ST values, which represent the degree of divergence between subpopulations (i.e. colonies; Nei Reference Nei1987), were greater than those observed among populations of Adélie and other penguin species whose nesting sites are separated by even larger geographical distances (Younger et al. Reference Younger, Emmerson, Southwell, Lelliott and Miller2015, Gorman et al. Reference Gorman, Talbot, Sonsthagen, Sage, Gravely, Fraser and Williams2017). The power of our findings may have been higher with a larger set of markers and a greater sample size (Gorman et al. Reference Gorman, Talbot, Sonsthagen, Sage, Gravely, Fraser and Williams2017). Our results are comparable with mitochondrial DNA data previously tested in our study colonies, which showed the lowest diversity levels of the Ross Sea and the highest relative abundance of the ‘A’ lineage with respect to the ‘RS’ lineage (Ritchie et al. Reference Ritchie, Millar, Gibb, Baroni and Lambert2004, Younger et al. Reference Younger, Emmerson, Southwell, Lelliott and Miller2015). Moreover, our results are comparable with those of Roeder et al. (Reference Roeder, Marshall, Mitchelson, Visagathilagar, Ritchie and Love2001), who similarly used seven microsatellite markers but detected no genetic structure.

Allelic richness and genetic diversity (i.e. Nei's diversity index) were highest in the large Inexpressible Island (including ~36,110 nests) colony and lowest in the small Edmonson Point colony (including ~2700 nests). Distributions of private alleles followed the same trend. We observed high homogeneity within each colony, with some overlap. Most variability was observed among colonies, which may represent three divergent demes. Accordingly, gene flow was the lowest between the most distant colonies (i.e. Edmonson Point and Inexpressible Island) and was highest between the Inexpressible Island colony and the intermediate one of Adélie Cove.

Although we evaluated a lower number of colonies than previous studies on the population genetics of the Adélie penguin, such studies did not show any population genetic structure among modern colonies, suggesting a higher level of dispersal (Roeder et al. Reference Roeder, Marshall, Mitchelson, Visagathilagar, Ritchie and Love2001, Gorman et al. Reference Gorman, Talbot, Sonsthagen, Sage, Gravely, Fraser and Williams2017). Geographical, environmental (i.e. including historical trophic and climatic) and behavioural constraints may influence dispersal distances, sometimes increasing individual movements among breeding colonies (Roeder et al. Reference Roeder, Marshall, Mitchelson, Visagathilagar, Ritchie and Love2001, Clucas et al. Reference Clucas, Dunn, Dyke, Emslie, Levy and Naveen2014, Gorman et al. Reference Gorman, Talbot, Sonsthagen, Sage, Gravely, Fraser and Williams2017). Lack of genetic structure in previously studied populations of the Adélie penguin has been related to the high number of emigrant individuals per generation among colonies corrected for population size (Nm s = 6–9) (Roeder et al. Reference Roeder, Marshall, Mitchelson, Visagathilagar, Ritchie and Love2001, Gorman et al. Reference Gorman, Talbot, Sonsthagen, Sage, Gravely, Fraser and Williams2017), possibly triggered by local climate change effects. Accordingly, climatic change appears to force penguins to move towards areas that better fulfil their ecological requirements in terms of habitat suitability and food availability during chick rearing (LaRue et al. Reference LaRue, Ainley, Swanson, Dugger, Lyver, Barton and Ballard2013, Gorman et al. Reference Gorman, Talbot, Sonsthagen, Sage, Gravely, Fraser and Williams2017). In the Antarctic Peninsula, where Gorman et al. (Reference Gorman, Talbot, Sonsthagen, Sage, Gravely, Fraser and Williams2017) carried out their study, large colonies of the only ‘A’ lineage occur and climate-driven alterations may have increased dispersal movements, resulting in a panmictic population (Clucas et al. Reference Clucas, Dunn, Dyke, Emslie, Levy and Naveen2014, Gorman et al. Reference Gorman, Talbot, Sonsthagen, Sage, Gravely, Fraser and Williams2017). Conversely, where climatic conditions are more stable or cooling (e.g. in our study areas, or at the southern-most latitudes of the Ross Sea), philopatry and dispersal may be more predictable (Gorman et al. Reference Gorman, Talbot, Sonsthagen, Sage, Gravely, Fraser and Williams2017). In other words, where climatic and environmental changes are less remarkable or conditions are more stable (e.g. in the Ross Sea), Adélie penguins appear to show higher philopatry (see also Dugger et al. Reference Dugger, Ballard, Ainley, Lyver and Schine2014). This would in turn limit the emigration rate among colonies in the Ross Sea, resulting in an evident genetic structure among colonies (i.e. high inter-colony heterogeneity), which has not been observed in warming areas in Antarctica (Clucas et al. Reference Clucas, Dunn, Dyke, Emslie, Levy and Naveen2014, Gorman et al. Reference Gorman, Talbot, Sonsthagen, Sage, Gravely, Fraser and Williams2017).

The Adélie penguin has coped with climate variability of the Southern Ocean over geological time. Population fluctuations in different areas have been the consequence of periods of abandonment during cooling ages (e.g. during the Last Glacial Maximum) followed by recolonization when new terrestrial breeding sites and open water became available (i.e. when ice sheets retreat following ice ages) (Younger et al. Reference Younger, Emmerson, Southwell, Lelliott and Miller2015). Radiocarbon dating from ornithogenic soils sampled at both abandoned and modern penguin colonies has shown Adélie penguin occupation histories and temporal fluctuations in the Ross Sea region over the last 45,000 years (Emslie et al. Reference Emslie, Coats and Licht2007). Accordingly, phylogenetic studies have found evidence that both monophyletic lineages of Adélie penguins (Ritchie et al. Reference Ritchie, Millar, Gibb, Baroni and Lambert2004, Younger et al. Reference Younger, Emmerson, Southwell, Lelliott and Miller2015) occur in Victoria Land, which may reflect the presence of a well-supported population genetic structure.

The opening of the western Ross Sea (Victoria Land coast) allowed the southern TNB area to be the first area to be reoccupied by Adélie penguins by ~8.2–7.7 ka (Mezgec et al. Reference Mezgec, Stenni, Crosta, Masson-Delmotte, Baroni and Braida2017), followed by two subsequent periods of abandonment due to unfavourable breeding conditions. Thus, following ice ages and interglacial periods, more recent reoccupation of central Victoria Land started ca. 5000–4000 bp. Edmonson Point was occupied ca. 2000–1100 bp (Emslie et al. Reference Emslie, Coats and Licht2007). The genetic structure and differences observed in our and previous studies (e.g. Ritchie et al. Reference Ritchie, Millar, Gibb, Baroni and Lambert2004) may reflect the population history of the Adélie penguin in the study areas following ice advances and retreats and subsequent colonization and immigration patterns.

Shepherd et al. (Reference Shepherd, Millar, Ballard, Ainley, Wilson and Haynes2005) compared the radiocarbon of ancient remains in ornithogenic soils with samples from modern colonies (i.e. Inexpressible Island). They highlighted that genetic variability in Adélie penguin populations of Victoria Land was probably affected by mega-icebergs. Icebergs break off from the retreating West Antarctic Ice Sheet and Ross Ice Shelf, periodically changing environmental conditions, which trigger the mixing of the populations through heightened emigration/immigration. Calving events, and the giant icebergs generated, are indeed responsible for the alteration of sea-ice circulation, polynya openings and the marine food web elsewhere in coastal Antarctica at different times (Michel et al. Reference Michel, Danis, Dubois, Eleaume, Fournier and Gallut2019). Such events may cause penguin colony breeding failure, as adults are wholly prevented from colony access when icebergs and extensive sea ice may become physical barriers to reach foraging areas or for returning to the nest in time to feed chicks (Dugger et al. Reference Dugger, Ballard, Ainley, Lyver and Schine2014, Ropert-Coudert et al. Reference Ropert-Coudert, Kato, Shiomi, Barbraud, Angelier and Delord2018). In central Victoria Land, the Drygalski Ice Tongue (Fig. 1) is an important regulator of the size of the TNB polynya (Davis et al. Reference Davis, Hofmann, Klinck, Piñones and Dinniman2017). Thus, major and minor ice-calving events may have altered sea-ice cover and shaped the marine environment and fauna near the TNB colonies (Mezgec et al. Reference Mezgec, Stenni, Crosta, Masson-Delmotte, Baroni and Braida2017).

The distribution and growth of Adélie penguin colonies are regulated by density-dependent factors, in addition to the quality of marine and terrestrial habitats (Ainley Reference Ainley2002, Lyver et al. Reference Lyver, Barron, Barton, Ainley, Pollard and Gordon2014, Southwell & Emmerson Reference Southwell and Emmerson2020). According to the source-sink theory (Hanski & Gaggiotti Reference Hanski and Gaggiotti2004), Inexpressible Island in particular as well as Adélie Cove may be ‘high-quality’ habitats and act as source populations, whereas Edmonson Point may represent a sink. A small population - despite available breeding ground - may be the result of the occupation of a low-quality patch. Small colonies that are more isolated (e.g. by fast ice, as in our case) have been described as being at a higher risk of extinction compared to large colonies (Bicknell et al. Reference Bicknell, Knight, Bilton, Campbell, Reid, Newton and Votier2014, Southwell & Emmerson Reference Southwell and Emmerson2020). Penguin access to Edmonson Point is limited by extensive fast ice throughout the breeding season. Edmonson Point also has the highest numbers of terrestrial predators (Table I). Skua predation is the major cause of egg and chick loss, accounting for up to 40% during the breeding season (S. Olmastroni, unpublished data 1996–2018). However, breeding success, diet, foraging range and adult survival rate for the Edmonson Point population are similar to those of other colonies (Ballerini et al. Reference Ballerini, Tavecchia, Olmastroni, Pezzo and Focardi2009, Olmastroni et al. Reference Olmastroni, Fattorini, Pezzo and Focardi2020) and other parts of the Antarctic (Jenouvrier et al. Reference Jenouvrier, Barbraud and Weimerskirch2006). Immature pre-breeders are important to population demography (Bicknell et al. Reference Bicknell, Knight, Bilton, Campbell, Reid, Newton and Votier2014), although Ballerini et al. (Reference Ballerini, Tavecchia, Olmastroni, Pezzo and Focardi2009) reported a low recruitment of birds marked as chicks (25%) for this colony.

Thus, the Edmonson Point colony, characterized by low recruitment rates as well as risky and more ‘stressful’ habitats (higher numbers of terrestrial predators and extensive fast ice) (Table I), may be considered a low-quality patch. Indeed, the colony seems at risk of extinction and is only able to maintain a stable population size by being sustained by immigration from other colonies (Ballerini et al. Reference Ballerini, Tavecchia, Pezzo, Jenouvrier and Olmastroni2015). Our present results of low genetic variability within this colony do not support this hypothesis. Quantification of the penguin immigration rate in southern Ross Sea colonies highlighted a rate of 1% population dispersal among neighbouring colonies, except for under unusual circumstances. Dugger et al. (Reference Dugger, Ballard, Ainley, Lyver and Schine2014) described how movements of breeding adults, survival and dispersal among clustered colonies may be altered by giant icebergs that separate colonies and also trap extensive sea ice, causing stressful conditions for several seasons. Under relatively stable environmental conditions, the degree of philopatry of the Adélie penguin, an adequate number of pre-breeders who survive to return to breed and a small immigration rate from other colonies may explain the maintenance of the Edmonson Point population, the low gene flux among colonies and the high genetic homogeneity within this colony (Fig. 4).

Our findings on genetic homogeneity within populations and an evident genetic structure amongst colonies contribute to insights into the population dynamics of a local cluster of Adélie penguin colonies. In fact, Inexpressible Island, Adélie Cove and Edmonson Point appear to be somewhat independent subpopulations maintained by a minimal dispersal mechanism and may thus interact as a meta-population. Future research would benefit from a more comprehensive set of markers and a larger sample size to compare results with other studies (e.g. Ritchie et al. Reference Ritchie, Millar, Gibb, Baroni and Lambert2004, Clucas et al. Reference Clucas, Dunn, Dyke, Emslie, Levy and Naveen2014, Gorman et al. Reference Gorman, Talbot, Sonsthagen, Sage, Gravely, Fraser and Williams2017). Moreover, further studies of the population genetic structure and dispersal are required to investigate the population dynamics and genetic structure of Adélie penguin populations in the TNB area. Increasing the study of penguin movements amongst colonies in the Ross Sea region over the long term would provide vital knowledge for the management and conservation of this long-lived seabird species.

Supplementary material

A supplemental methods section will be found at https://doi.org/10.1017/S0954102021000067.

Acknowledgements

The authors are grateful to PNRA ('Programma Nazionale di Ricerche in Antartide') and MZS (Mario Zucchelli Station) staff for their logistic support during the XXXIII Italian Antarctic Expedition. We acknowledge the use of imagery from the NASA Worldview application (https://worldview.earthdata.nasa.gov), part of the NASA Earth Observing System Data and Information System (EOSDIS), and the Norwegian Polar Institute's Qantarctica package for the map in Fig. 1. Massimo Frezzotti and David Ainley provided insightful comments and fruitful discussions on the manuscript. We thank Prof Filippo Barbanera and Prof Francesco Nardi for recommendations on genetic analyses, as well as Dr Monica Scali and Dr Rita Vignani for STR sequencing. Diego Cantini carried out laboratory work. Two anonymous reviewers kindly took the time to improve our manuscript with their comments.

Author contributions

EM participated in conceiving this study, carried out genetic and relevant statistical analyses and drafted the manuscript. CB carried out genetic and relevant statistical analyses. AC supervised the molecular analysis. LB participated in planning the fieldwork and carried out the fieldwork. NF participated in planning the fieldwork, carried out the fieldwork and participated in writing. FF participated in conceiving this study and writing. SO conceived and designed this study, coordinated the research, planned and coordinated the fieldwork, carried out the fieldwork, participated in interpreting the data and drafted the manuscript. All authors read and approved the final manuscript.

Financial support

This analysis was funded by PNRA2016 AZ1.11 ‘PenguinERA’ project, EM grant DDG Rep. 1985/2018 prot. n° 192517/111-12, 12-12-2018.

Ethical approval

All sampling followed SCAR's Code of Conduct for the Use of Animals for Scientific Purposes in Antarctica (https://www.scar.org/policy/scar-codes-of-conduct) and under permission released from PNRA ('Programma Nazionale di Ricerche in Antartide').

Details of data deposit

The datasets generated and/or analysed during the current study are stored at University of Siena and Museo Nazionale dell'Antartide in Siena and are available from the corresponding author upon reasonable request.

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Figure 0

Fig. 1. Map of the Victoria Land coast and location of the three colonies. Location of the Italian research station MZS is also shown. Landsat image from Qantarctica3 (https://www.npolar.no/quantarctica), LIMA Landsat image mosaic of Antarctica (15/240 m) USGS/Remote Sensing of Environment, 2008. MZS = Mario Zucchelli Station; TNB = Terra Nova Bay.

Figure 1

Table I. Ecological features of the three colonies located in central Victoria Land, Ross Sea, Antarctica. The linear distance to Terra Nova Bay polynya and range of fast-ice extension were measured using EOSDIS Worldview (https://worldview.earthdata.nasa.gov) to the best image available in late October, mid-December and mid-January from 2000 to 2018. The approximate size of colony area was measured with Google Earth Pro on images 23 February 2010, 27 November 2011 and 2 December 2011 for Edmonson Point, Adélie Cove and Inexpressible Island, respectively.

Figure 2

Table II. Characterization of microsatellite loci of Adélie penguins used in our work.

Figure 3

Fig. 2. Allelic frequencies for each locus for all studied colonies: arrows on the x-axis show private alleles.

Figure 4

Table III. Polymorphic informative content (PIC) and allelic richness for each locus and for each colony, corrected for population size.

Figure 5

Fig. 3. Tridimensional factorial correspondence analysis, including all of the sampled individuals (yellow = Adélie Cove; red = Inexpressible Island; blue = Edmonson Point). Axes show the variables explaining the variability of the genetic diversity in our dataset.

Figure 6

Table IV. Hardy-Weinberg equilibrium multilocus test and tests for deficiency and excess of heterozygotes.

Figure 7

Table V. Results of the analysis of molecular variance between colonies (FST) and Nei's diversity indices for genetic diversity (average gene diversity ± standard deviation).

Figure 8

Fig. 4. Probabilities of assignment of Adélie penguin individuals to putative population clusters following the Bayesian analysis of population structure for six microsatellite loci per individual. Each individual penguin is represented by vertical lines and different colours represent different clusters (blue = Edmonson Point; yellow = Adélie Cove; red = Inexpressible Island). The structure plot was obtained without prior location information.

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