Effective population size and the genetic consequences of commercial whaling on the humpback whales (<i>Megaptera novaeangliae</i>) from Southwestern Atlantic Ocean

Cypriano-Souza, Ana Lúcia; da Silva, Tiago Ferraz; Engel, Márcia H.; Bonatto, Sandro L.

doi:10.1590/1678-4685-GMB-2017-0052

Abstract

Genotypes of 10 microsatellite loci of 420 humpback whales from the Southwestern Atlantic Ocean population were used to estimate for the first time its contemporary effective (N_e) and census (N_c) population sizes and to test the genetic effect of commercial whaling. The results are in agreement with our previous studies that found high genetic diversity for this breeding population. Using an approximate Bayesian computation approach, the scenario of constant N_e was significantly supported over scenarios with moderate to strong size changes during the commercial whaling period. The previous generation N_c (N_e multiplied by 3.6), which should corresponds to the years between around 1980 and 1990, was estimated between ~2,600 and 6,800 whales (point estimate ~4,000), and is broadly compatible with the recent abundance surveys extrapolated to the past using a growth rate of 7.4% per annum. The long-term N_c in the constant scenario (point estimate ~15,000) was broadly compatible (considering the confidence interval) with pre-whaling catch records estimates (point estimate ~25,000). Overall, our results shown that the Southwestern Atlantic Ocean humpback whale population is genetically very diverse and resisted well to the strong population reduction during commercial whaling.

Keywords:
Commercial whaling; bottleneck; humpback whale; microsatellites; demography

Introduction

Estimation of historic (pre-whaling) and contemporary population sizes are important to offer guidelines for managing and restoring populations that suffered overexploitation, such as those of baleen whales (Baker and Clapham, 2004Baker CS and Clapham PJ (2004) Modeling the past and future of whales and whaling. Trends Ecol Evol 19:365-371.; Jackson et al., 2008Jackson JA, Patenaude NJ, Carroll EL and Baker CS (2008) How few whales were there after whaling? Inference from contemporary mtDNA diversity. Mol Ecol 17:236-251.). Although abundance is obviously important in the very short term, effective population size (N_e) is a key parameter in the long term, and essential for population genetics, evolutionary biology and conservation biology (Schwartz et al., 1998Schwartz MK, Tallmon DA and Luikart G (1998) Review of DNA-based census and effective population size estimators. An Conserv 1:293-299.; Charlesworth, 2009Charlesworth B (2009) Effective population size and patterns of molecular evolution and variation. Nat Rev Genet 10:195-205.). It is directly related to evolutionary processes, such as rates of genetic drift and loss of genetic variability, levels of inbreeding, and effectiveness of selection (Frankham et al., 2002Frankham R, Ballou JD and Briscoe DA (2002) Introduction to Conservation Genetics. Cambridge University Press, Cambridge, 617 p.). Generally, N_e is lower than the census population size (N_c) since individuals do not contribute genes equally to the next generation. One important advance has been the development of methods to estimate N_e from genetic data (Schwartz et al., 1998Schwartz MK, Tallmon DA and Luikart G (1998) Review of DNA-based census and effective population size estimators. An Conserv 1:293-299.; Leberg, 2005Leberg P (2005) Genetic approaches for estimating the effective size of populations. J Wildl Manage 69:1385-1399.; Waples, 2005Waples RS (2005) Genetic estimates of contemporary effective population size: To what time periods do the estimates apply? Mol Ecol 14:3335-3352.; Palstra and Ruzzante, 2008Palstra FP and Ruzzante DE (2008) Genetic estimates of contemporary effective population size: what can they tell us about the importance of genetic stochasticity for wild population persistence? Mol Ecol 17:3428-3447.; Luikart et al., 2010Luikart G, Ryman N, Tallmon DA, Schwartz MK and Allendorf FW (2010) Estimation of census and effective population sizes: the increasing usefulness of DNA-based approaches. Conserv Genet 11:355-373.). This approach has provided important information to investigate whale population dynamics, although N_e estimates are only available for some species and in a few areas (e.g. Rooney et al., 1999Rooney AP, Honeycutt RL, Davis SK and Derr JN (1999) Evaluating a putative bottleneck in a population of bowhead whales from patterns of microsatellite diversity and genetic disequilibria. J Mol Evol 49:682-690., 2001Rooney AP, Honeycutt RL and Derr JN (2001) Historical population size change of bowhead whales inferred from DNA sequence polymorphism data. Evolution 55:1678-1685.; Waldick et al., 2002Waldick RC, Kraus S, Brown M and White BN (2002) Evaluating the effects of historic bottleneck events: An assessment of microsatellite variability in the endangered North Atlantic right whale. Mol Ecol 11:2241-2249.; Roman and Palumbi, 2003Roman J and Palumbi S (2003) Whales before whaling in North Atlantic. Science 301:508-510.; Alter et al., 2007Alter SE, Rynes E and Palumbi SR (2007) DNA evidence for historic population size and past ecosystem impacts of gray whales. Proc Natl Acad Sci U S A 104:15162-15167., 2012Alter SE, Newsome SD and Palumbi SR (2012) Prewhaling genetic diversity and population ecology in eastern pacific grey whales: insights from ancient DNA and stable isotopes. PLoS One 7:e35039.; Ruegg et al., 2010Ruegg KC, Anderson EC, Baker CS, Vant M, Jackson JA and Palumbi SR (2010) Are Antarctic minke whales unusually abundant because of 20th century whaling? Mol Ecol. 19:281-291., 2013Ruegg KC, Rosenbaum HC, Anderson EC, Engel MH, Rothchild A, Baker CS and Palumbi SR (2013) Long-term population size of the North Atlantic humpback whale within the context of worldwide population structure. Conserv Genet 14:103-114.). Another relevant information for management is knowing the impact induced by the extreme reduction of the abundance during 20^th century whaling activities on the genetic diversity of the species, since the loss of genetic variation can impact population viability leading to its premature extinction. However, although conservation actions should prioritize the populations with minor genetic diversity, it is not known which populations went extinct following such bottlenecks.

Humpback whales, Megaptera novaeangliae (Borowski 1781), were among the most exploited baleen whale species by commercial whaling. The populations are found throughout the world’s ocean basins, undertaking annual migrations between the low latitude waters, where they breed and calve during the winter-spring months, and the high latitude waters, where they feed during the summer (Dawbin, 1966Dawbin W (1966) The seasonal migratory cycle of the humpback whale. In: Norris KS (ed) Whales, Dolphins and Porpoises. University of California Press, Berkeley, pp 145-170.). The International Whaling Commission (IWC) recognizes seven humpback whale breeding stocks (termed A-G) in the Southern Hemisphere (International Whaling Commission, 2015International Whaling Commission (2015) Report of the Scientific Committee. Annex H: Report of the sub-committee on other Southern Hemisphere whale stocks. J Cetacean Res Manage 16:196-221.). In the Southwestern Atlantic Ocean, the humpback whale population wintering along the Brazilian coast (~ 5° to 23° S) (Andriolo et al., 2010Andriolo A, Kinas PG, Engel MH and Martins CCA (2010) Humpback whale population estimates and distribution along the Brazilian breeding ground. Endanger Species Res 11:233-243.) is recognized as the Breeding Stock A (BSA). The main mating and calving area for this population is in the Abrolhos Bank (16°40’- 19°30’ S and 37°25’- 39°45’ W), where most whales concentrate (about 85% of the density) during the breeding season (Andriolo et al., 2010Andriolo A, Kinas PG, Engel MH and Martins CCA (2010) Humpback whale population estimates and distribution along the Brazilian breeding ground. Endanger Species Res 11:233-243.; Bortolotto et al., 2016aBortolotto GA, Danilewicz D, Andriolo A, Secchi ER and Zerbini AN (2016a) Whale, whale, everywhere: Increasing abundance of Western South Atlantic Humpback whales (Megaptera novaeangliae) in their wintering grounds. PLoS One 11:e0164596.). However, in recent years, the number of sightings and strandings has increased beyond the BSA range, indicating recovery of this population and likely expansion of its distribution range (Pretto et al., 2009Pretto DJ, Andrade MCM, Oliveira JM and Oliveira MGA (2009) First record of a humpback whale, Megaptera novaeangliae (Borowski, 1781), stranding in Pará State, Northern coast of Brazil. Braz J Biol 69:1207-1208.; Wedekin et al., 2014Wedekin LL, Rossi-Santos M, Baracho C, Cypriano-Souza AL and Simões-Lopes PC (2014) Cetacean records along a coastal-offshore gradient in the Vitória-Trindade Chain, western South Atlantic Ocean. Braz J Biol 74:137-144.; Bortolotto et al., 2016bBortolotto GA, Kolesnikovas CKM, Freire AS and Simões-Lopes PC (2016b) Young humpback whale Megaptera novaeangliae feeding in Santa Catarina coastal waters, Southern Brazil, and a ship strike report. Mar Biodivers Rec 9:29.). This population migrates to summer feeding grounds around South Georgia and South Sandwich islands in the Southern Ocean (Engel and Martin, 2009Engel MH and Martin AR (2009) Feeding grounds of the western South Atlantic humpback whale population. Mar Mamm Sci 25:964-969.; Zerbini et al., 2006Zerbini AN, Andriolo A, Heide-Jorgensen MP, Pizzorno JL, Maia YG, VanBlaricom GR, DeMaster DP, Simões-Lopes PC, Moreira S and Bethlem C (2006) Satellite-monitored movements of humpback whales Megaptera novaeangliae in the Southwest Atlantic Ocean. Mar Ecol Prog Ser 313:295-304., 2011aZerbini AN, Andriolo A, Heide-Jorgensen MP, Moreira S, Pizzorno JL, Maia YG, VanBlaricom G and DeMaster DP (2011a) Migration and summer destinations of humpback whales (Megaptera novaeangliae) in the western South Atlantic Ocean. J Cetac Res Manage 3:113-118.).

Commercial whaling during the 20^th century reduced the worldwide humpback whale population to a small fraction of its pre-exploitation abundance (Tønnessen and Johnsen, 1982Tønnessen JN and Johnsen AO (1982) The History of Modern Whaling. University of California Press, Berkeley, 755 p.). In the Southern Hemisphere, approximately 200,000 humpback whales were hunted from 1904 to 1972, after accounting for the illegal Soviet whaling, mainly by whaling operations around Antarctica feeding areas (Findlay, 2001Findlay KP (2001) A review of humpback whale catches by modern whaling operations in the Southern Hemisphere. Mem Queensl Mus 47:411-420.; Clapham et al., 2009Clapham PJ, Mikhalev Y, Franklin W, Paton D, Baker CS, Ivashchenko IV and Brownell Jr RL (2009) Catches of humpback whales, Megaptera novaeangliae, by the Soviet Union and other nations in the Southern Ocean, 1947-1973. Mar Fish Rev 71:39-43.; Allison, 2010Allison C (2010) International Whaling Commission individual catch database, Version 5.0. Available from the IWC Secretariat.). In Brazil, pre-modern whaling began in the early 1600s, ending in the 1830s in southern of the country, with the collapse of the southern right whale population, but lasted until the 1920s in northeastern region due to the high density of humpback whales, mainly in Caravelas, Bahia. It was estimated that between 11,000 and 32,000 humpback whales were captured from 1830 to 1924 (Morais et al., 2017Morais IOB, Danilewicz D, Zerbini AN, Edmundson W, Hart IB and Bortolotto GA (2017) From the southern right whale hunting decline to the humpback whaling expansion: A review of whale catch records in the tropical western South Atlantic Ocean. Mammal Rev 47:11-23.). Modern whaling operations that began in the 20^th century expanded the activities of the whaling stations mainly for the coasts of Costinha (7° S) (between 1910 and 1967) and Cabo Frio (23° S) (between 1960 and 1963), where 352 humpbacks were caught in 1913, but only around 13 whales in 1967, already indicating a significant population size reduction (Paiva and Grangeiro, 1965Paiva MP and Grangeiro BF (1965) Biological investigations on the whaling seasons 1960-1963, off the northeastern coast of Brazil. Arq Estac Biol Mar Univ Ceara 5:29-64., 1970Paiva MP and Grangeiro BF (1970) Investigations on the whaling seasons 1964-1967, off the northeastern coast of Brazil. Arq Ciênc Mar 10:111-126.; Williamson, 1975Williamson GR (1975) Minke whales off Brazil. Sci Rep Whales Res Inst 27:37-59.). In addition, modern whaling activities in high-density areas in the Antarctic and Sub-Antarctic feeding grounds increased the annual catch to several thousand whales (Findlay, 2001Findlay KP (2001) A review of humpback whale catches by modern whaling operations in the Southern Hemisphere. Mem Queensl Mus 47:411-420.). Only in the surroundings of the South Georgia Island about 22,717 humpback whales were killed between 1904 and 1915, when the exploitation of this stock was most extensive (Edmundson and Hart, 2014Edmundson W and Hart I (2014) A História da Caça de Baleias no Brasil: De Peixe Real a Iguaria Japonesa. DISAL, São Paulo, 312 p.). Although the species have been protected since 1966, the former Soviet Union fleet took humpback whales illegally off the central coast of Brazil until 1973 (Yablokov et al., 1998Yablokov AV, Zemsky VA, Mikhalev YA, Tornosov VV and Berzin AA (1998) Data on Soviet whaling in the Antarctic in 1947-1972 (population aspects). Russ J Ecol 29:38-42.). It was estimated that 48,477 humpbacks were caught by Soviet whaling in the Southern Hemisphere between 1948 and 1973, of which 1,407 were caught in the South Atlantic Ocean between 1960 and 1967 (Berzin, 2008Berzin AA (2008)The truth about Soviet whaling. Mar Fish Rev 70:4-60.).

The BSA population size before the exploitation by modern whaling was estimated using catch records to nearly 24,700 individuals, and it reached its lowest numbers in the late 1950s, when there were less than 500 individuals (Zerbini et al., 2011bZerbini AN, Ward EJ, Kinas PG, Engel MH and Andriolo A (2011b) A Bayesian assessment of the conservation status of humpback whales (Megaptera novaeangliae) in the western South Atlantic Ocean. J Cetac Res Manage 3:131-144.). Presently this population is recovering fast (growth rate of 7.4% per annum, Ward et al., 2011Ward E, Zerbini AN, Kinas PG, Engel MH and Andriolo A (2011) Estimates of population growth rates of humpback whales (Megaptera novaeangliae) in the wintering grounds off the coast of Brazil (Breeding Stock A). J Cetac Res Manage 3:145-149.) and the abundance in 2015Gilbert KJ and Whitlock MC (2015) Evaluating methods for estimating local effective population size with and without migration. Evolution 69:2154-2166. was estimated around 12,123 individuals (Pavanato et al., 2017Pavanato HJ, Wedekin LL, Guilherme-Silveira FR, Engel MH and Kinas PG (2017) Estimating humpback whale abundance using hierarchical distance sampling. Ecol Modell 358:10-18.). Interestingly, despite these well-documented census size changes in the BSA, recent studies have not detected a genetic bottleneck, that is, a significant reduction in the effective population size of this population (Engel et al., 2008Engel MH, Fagundes NJR, Rosenbaum HC, Leslie MS, Ott PH, Schmitt R, Secchi E, Dalla Rosa L and Bonatto SL (2008) Mitochondrial DNA diversity of the Southwestern Atlantic humpback whale (Megaptera novaeangliae) breeding area off Brazil, and the potential connections to Antartic feeding areas. Conserv Genet 9:1253-1262.; Cypriano-Souza et al., 2010Cypriano-Souza AL, Fernández GP, Lima-Rosa CAV, Engel MH and Bonatto SL (2010) Microsatellite genetic characterization of the humpback whale (Megaptera novaeangliae) Breeding Ground off Brazil (Breeding Stock A). J Hered 101:189-200.). The absence of a signal for a genetic bottleneck was explained by the low intensity (in terms of duration and minimum population size) of this bottleneck (Engel et al., 2008Engel MH, Fagundes NJR, Rosenbaum HC, Leslie MS, Ott PH, Schmitt R, Secchi E, Dalla Rosa L and Bonatto SL (2008) Mitochondrial DNA diversity of the Southwestern Atlantic humpback whale (Megaptera novaeangliae) breeding area off Brazil, and the potential connections to Antartic feeding areas. Conserv Genet 9:1253-1262.; Cypriano-Souza et al., 2010Cypriano-Souza AL, Fernández GP, Lima-Rosa CAV, Engel MH and Bonatto SL (2010) Microsatellite genetic characterization of the humpback whale (Megaptera novaeangliae) Breeding Ground off Brazil (Breeding Stock A). J Hered 101:189-200.). However, these studies used standard methods (heterozygosity excess, mode-shift and M-ratio tests), that have reduced power to detect moderate bottlenecks (Peery et al., 2012Peery MZ, Kirby R, Reid BN, Stoelting R, Doucet-Bëer E, Robinson S, Vásquez-Carrillo C, Pauli JN and Palsbøll PJ (2012) Reliability of genetic bottleneck tests for detecting recent population declines. Mol Ecol 21:3403-3418.). Besides, none of the genetic studies so far has provided estimates of N_e for the Brazilian humpback whale population.

The present study aims to estimate the effective and census population sizes of the Southwestern Atlantic Ocean humpback population, and investigate the effects of commercial whaling in the 20^th century on its genetic diversity, based on the analysis of genotypes constructed from 10 microsatellite loci for 420 individuals sampled off the Brazilian coast.

Materials and Methods

Sample collection and DNA extraction

Between 1999 and 2007, 379 tissue samples of humpback whales were collected by the biopsy dart procedure (Lambertsen, 1987Lambertsen RH (1987) A biopsy system for large whales and its use for cytogenetics. J Mammal 68:443-445.) at two geographic locations off the Brazilian coast, the Abrolhos Bank (n = 332), in southern Bahia and northern Espírito Santo, and Praia do Forte (n = 47) in northern Bahia (Figure 1). Only adult animals were sampled within the social groups, which showed a body size longer than 11 meters. Additional samples (n = 41) resulted from individuals adults stranded along the coasts of both states. Samples were preserved in 70% ethanol and were stored at -20 °C until processed. Genomic DNA was extracted using proteinase K digestion followed by phenol/chloroform extraction method (Palsbøll et al., 1995Palsbøll PJ, Clapham PJ, Mattila DK, Larsen F, Sears R, Siegismund HR, Sigurjónsson J, Vásquez O and Artander P (1995) Distribution of mtDNA haplotypes in North Atlantic humpback whales: the influence of behaviour on population structure. Mar Ecol Prog Ser 116:1-10.) or using the DNeasy Blood and Tissue kit (QIAGEN).

Figure 1
Map of the surveyed areas, showing the geographic locations of the two sampling sites (zoom) of the humpback whale breeding ground off the Brazilian coast (BSA).

Microsatellite genotyping

Samples were screened for genetic variation at 10 microsatellite loci [seven dinucleotides: EV1, EV37, EV94, EV96 (Valsecchi and Amos, 1996Valsecchi E and Amos W (1996) Microsatellite markers for the study of cetacean populations. Mol Ecol 5:151-156.), 199/200, 417/418, 464/465 (Schlötterer et al., 1991Schlötterer C, Amos B and Tautz D (1991) Conservation of polymorphic simple sequence loci in cetacean species. Nature 354:63-65.), and three tetranucleotides: GATA028, GATA053, GATA417, (Palsbøll et al., 1997Palsbøll PJ, Bérubé M and Jorgensen H (1997) Primers for the amplification of tri- and tetramer microsatellite loci in baleen whales. Mol Ecol 6:893-895.)]. Genotypes of 268 of the individuals used here were described previously in Cypriano-Souza et al. (2010)Cypriano-Souza AL, Fernández GP, Lima-Rosa CAV, Engel MH and Bonatto SL (2010) Microsatellite genetic characterization of the humpback whale (Megaptera novaeangliae) Breeding Ground off Brazil (Breeding Stock A). J Hered 101:189-200., and genotyping of the additional samples was conducted exactly as described in that study, including in the same machine.

Genetic variation

The program MICRO-CHECKER v.2.2.3 (Van Oosterhout et al., 2004Van Oosterhout C, Hutchinson WF, Wills DPM and Shipley P (2004) MICRO-CHECKER: software for identifying and correcting genotyping errors in microsatellite data. Mol Ecol Notes 4:535-538.) was used to identify possible null alleles, large allele dropout, and scoring errors due to stutter peaks. While in the previous study (Cypriano-Souza et al., 2010Cypriano-Souza AL, Fernández GP, Lima-Rosa CAV, Engel MH and Bonatto SL (2010) Microsatellite genetic characterization of the humpback whale (Megaptera novaeangliae) Breeding Ground off Brazil (Breeding Stock A). J Hered 101:189-200.) locus 417/418 showed a weak sign of null alleles, this was not detected here, since homozygous excess was insufficient to suggest the presence of null alleles.

Genetic diversity was measured as the number of alleles per locus (K), observed and expected heterozygosities (H_O and H_E, respectively) under Hardy-Weinberg equilibrium (HWE) (Nei, 1978Nei M (1978) Estimation of average heterozygosity and genetic distance from a small number of individuals. Genetics 89:583-590.), using FSTAT v.2.9.3 (Goudet, 2002Goudet J (2002) FSTAT: A program to estimate and test gene diversities and fixation indices. Institute of Ecology, Lausanne.). FSTAT was also used to calculate the measure of F_IS (Weir and Cockerham, 1984Weir BS and Cockerham CC (1984) Estimating F-statistics for the analysis of population structure. Evolution 38:1358-1370.). Deviations from HWE for each locus (Guo and Thompson, 1992Guo S and Thompson E (1992) Performing the exact test of Hardy-Weinberg proportion for multiples alleles. Biometrics 48:361-372.) and linkage disequilibrium between loci were tested using ARLEQUIN 3.5 (Excoffier and Lischer, 2010Excoffier L and Lischer HEL (2010). Arlequin suite ver 3.5: A new series of programs to perform population genetics analyses under Lynux and Windows. Mol Ecol Resour 10:564-567.), corrected for simultaneous comparisons with the sequential Bonferroni test (Rice, 1989Rice WR (1989) Analyzing table of statistical tests. Evolution 43:223-225.).

N_e estimation

Two methods were used to estimate effective population size (N_e), both assuming a closed population with discrete generations and random variance in reproductive success. The program NeEstimator v.2.01 (Do et al., 2014Do C, Waples RS, Peel D, Macbeth GM, Tillett BJ and Ovenden JR (2014) NeEstimator v2: Re-implementation of software for the estimation of contemporary effective population size (Ne) from genetic data. Mol Ecol Resour 14:209-214.) was used to estimate the parental generation N_e from genotypic data based on the linkage disequilibrium (LD) method, which calculates separate estimates using different criteria for excluding rare alleles. We used the random mating model and the following critical values (P_crit): 0.05, 0.02 and 0.01, as suggested in the program manual.

An approximate Bayesian computation (ABC) approach implemented in the program DIYABC v.1.0.46 (Cornuet et al., 2008Cornuet JM, Santos F, Beaumont MA, Robert CP, Marin JM, Balding DJ and Estoup A (2008) Inferring population history with DIYABC: A user-friendly approach to approximate Bayesian computation. Bioinformatics 24:2713-2719., 2010Cornuet JM, Ravigné V and Estoup A (2010) Inference on population history and model checking using DNA sequence and microsatellite data with the software DIYABC (v1. 0). BMC Bioinformatics 11:401.) was also used to test four different scenarios based in the possible demographic history of this humpback whale population during commercial whaling in the 20^th century. Scenario 1 is a constant size population (no bottleneck), scenario 2 consisted of a population that is still experiencing a bottleneck, scenario 3 is a population that expanded recently from a bottleneck, and scenario 4 is a population that experienced a transitory bottleneck (Figure 2a). The priors for all parameters were uniformly distributed between specified minimum and maximum values (Table 1 and Figure 2a), which were based on the available information of the whaling history of this population and its present day census data (see Introduction). The demographic parameters were: Scenario 1: N_e (long-term historical N_e); Scenario 2: N_e2 (current N_e), N_a2 (pre-bottleneck N_e); Scenario 3: N_e3 (current N_e), N_a3 (N_e during bottleneck); t (time since demographic change in scenarios 2 and 3); Scenario 4: N_e4 (current N_e), N_b (N_e during bottleneck), N_a4 (pre-bottleneck N_e), t2 and t1 (time since the beginning and end of the bottleneck, respectively). All times are in number of generations [generation time of 18 years taking into account the range between 12 and 24 years estimated for the humpback whales (Chittleborough, 1965Chittleborough RG (1965) Dynamics of two populations of the humpback whale, Megaptera novaeangllae (Borowski). Aust J Mar Freshw Res 16:33-128.; Roman and Palumbi, 2003Roman J and Palumbi S (2003) Whales before whaling in North Atlantic. Science 301:508-510.)] from the present, with t2 > t1. The 10 microsatellites loci were assumed to evolve under the generalized stepwise mutation model (GSM) (Estoup et al., 2002Estoup A, Jarne P and Cornuet JM (2002) Homoplasy and mutation model at microsatellite loci and their consequences for population genetics analysis. Mol Ecol 11:1591-1604.) with the widely used mutation rate (μ) range for mammals, from 10^-4 to 10^-3 per generation (Ellegren, 1995Ellegren H (1995) Mutation rates at porcine microsatellite loci. Mamm Genome 6:376-377., Whittaker et al., 2003Whittaker JC, Harbord RM, Boxall N, Mackay I, Dawson G and Sibly RM (2003) Likelihood-based estimation of microsatellite mutation rates. Genetics 164:781-787., Hoffman et al., 2011Hoffman JI, Grant SM, Forcada J and Phillips CD (2011) Bayesian inference of a historical bottleneck in a heavily exploited marine mammal. Mol Ecol 20:3989-4008.) and the coefficients of geometric distribution (P) from 0.1 to 0.7. Motif sizes and alleles ranges followed the empirical data of each locus. The summary statistics were the mean number of alleles (A), genetic diversity (H_E), allelic size range (AR), and Garza-Williamson’s index (M). A total of 3,000,000 simulations were performed to generate the reference table, using the four scenarios according to their prior probability and their parameter values drawn from the prior distributions. The posterior probability of each scenario was assessed using both direct estimate and logistic regression approaches using between 500 and 30,000 best simulations. Under an ABC approach, the best scenario is the one with the simulated data set closest to observed data set. For the best scenario, the posterior distribution of the parameters was estimated using logit transformation for the 8,000 best simulations.

Figure 2
Demographic scenarios for humpback whales from BSA. (a) The four demographic scenarios tested with the DIYABC approach: 1 - constant population, 2 - bottlenecked population, 3 - expanded population, 4 - population with a transitory bottleneck. Demographic parameters: N_e - long-term; N_e2, N_e3 and N_e4 - current; N_a2 and N_a4 - pre-bottleneck; N_a3 and N_b - during bottleneck. The posterior probability of each scenario is given at the bottom. (b) Posterior probabilities (y-axis) with confidence intervals of the four scenarios in different numbers of selected closest-to-observed simulations based on the direct estimate, and (c) logistic regression (only for scenario 1).

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Table 1
Prior values (minimum and maximum, with uniform distribution) for the parameters used for the four demographic scenarios () in the DIYABC approach. Effective sizes are in number of individuals and times are in number of generations (generation time of 18 years).

We converted the effective sizes (N_e) obtained in each method to the census sizes (N_c) as follows. First, the ratio of mature adults to the effective number of adults (N_T:N_e) approaches 2 for most populations, and was based on the equation N_e = N/(2 - T^-1) from Nunney and Elam (1994)Nunney L and Elam DR (1994) Estimating the effective size of conserved populations. Conserv Biol 8:175-184., where T is the generation length. Second, the proportion of juveniles in the population (number of adults + juveniles)/(number of adults), was estimated between 1.6 to 2.0 for humpback whales based on catch and survey data (Chittleborough, 1965Chittleborough RG (1965) Dynamics of two populations of the humpback whale, Megaptera novaeangllae (Borowski). Aust J Mar Freshw Res 16:33-128., Roman and Palumbi, 2003Roman J and Palumbi S (2003) Whales before whaling in North Atlantic. Science 301:508-510.). Therefore, multiplying the two ratios, the average ratio of census population size to effective population size was 3.6, with a variation from 3.2 to 4.0, which has also been used in previous studies (Roman and Palumbi, 2003Roman J and Palumbi S (2003) Whales before whaling in North Atlantic. Science 301:508-510.; Alter et al., 2007Alter SE, Rynes E and Palumbi SR (2007) DNA evidence for historic population size and past ecosystem impacts of gray whales. Proc Natl Acad Sci U S A 104:15162-15167., 2012Alter SE, Newsome SD and Palumbi SR (2012) Prewhaling genetic diversity and population ecology in eastern pacific grey whales: insights from ancient DNA and stable isotopes. PLoS One 7:e35039.; Ruegg et al., 2010Ruegg KC, Anderson EC, Baker CS, Vant M, Jackson JA and Palumbi SR (2010) Are Antarctic minke whales unusually abundant because of 20th century whaling? Mol Ecol. 19:281-291., 2013Ruegg KC, Rosenbaum HC, Anderson EC, Engel MH, Rothchild A, Baker CS and Palumbi SR (2013) Long-term population size of the North Atlantic humpback whale within the context of worldwide population structure. Conserv Genet 14:103-114.).

Results

Genetic variability

Individual multilocus genotypes were on average 98.5% complete. Summary statistics are presented in Table 2. The number of alleles identified at the 10 microsatellite loci ranged from five (EV1) to 18 (GATA417), with a mean of 12.6. The mean observed (H_O) heterozygosity was 0.736, ranging from 0.553 (EV1) to 0.923 (GATA417), and the mean expected (H_E) heterozygosity was 0.746, ranging from 0.532 (EV1) to 0.923 (EV37). Population-wide F_IS values were low for all loci (below 0.05), except for the locus GATA053 (F_IS = 0.053) and the locus 417/418 (F_IS = 0.068), but these values were not significant. Moreover, no evidence of null alleles and no significant deviation from HWE expectations were seen at any of the loci. Pairwise comparison of allele frequencies revealed no significant linkage disequilibrium after Bonferroni correction.

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Table 2
Summary statistics for 10 microsatellite loci genotyped for the humpback whale population off Brazil. Rep, repeat motif length in base pairs; K, number of alleles; H_O, observed heterozygosity; H_E, expected heterozygosity; F_IS, inbreeding coefficient (*P < 0.005 based on 180 randomizations).

N_e estimates

The contemporary N_e estimated with NeEstimator ranged from 1,039 (P_crit = 0.01, 95% CI = 731 - 1,707) to 1,537 individuals (P_crit = 0.05, 95% CI = 754 - 18,851) for the different critical values. However, P_crit = 0.02 is indicated to provide better precision (Waples, 2006Waples RS (2006) Evaluation of a genetic method for estimating contemporary population size in cetaceans based on linkage disequilibrium. Paper SC/58/AWMP2. International Whaling Commission Scientific Committee, St. Kitts, 12 p.), therefore our more reliable estimate was 1,078 whales (95% CI = 738 - 1,884). From the above values the census population size (N_c) was calculated as 3,880 individuals (95% CI = 2,656 - 6,782).

In the comparison of the four scenarios (constant population, bottlenecked, expanded, and transitory bottleneck) using the ABC approach implemented in DIYABC, the constant population (no demographic changes) scenario was highly supported (posterior probability > 0.99) in relation to the other scenarios with demographic changes, in both the direct estimate and logistic regression approaches (Figure 2b,c). In the constant scenario, the mode of the posterior distribution for the long term N_e was 4,170 (95% CI = 2,330 - 26,600) (Figure 3). The mode for the N_c was then 15,012 (95% CI = 8,388 - 95,760), using the 3.6 census/effective ratio.

Figure 3
Posterior distribution (in green) of the parameter N_e from the best-supported scenario (Scenario 1, constant population, see ) as estimated in the program DIYABC. The red line is the prior distribution for N_e.

Discussion

Our extended sampling confirms our previous results on the high nuclear DNA diversity of the humpback whale population that winters off the Brazilian coast (BSA), which is also compatible with its high mtDNA variability (Engel et al., 2008Engel MH, Fagundes NJR, Rosenbaum HC, Leslie MS, Ott PH, Schmitt R, Secchi E, Dalla Rosa L and Bonatto SL (2008) Mitochondrial DNA diversity of the Southwestern Atlantic humpback whale (Megaptera novaeangliae) breeding area off Brazil, and the potential connections to Antartic feeding areas. Conserv Genet 9:1253-1262.; Cypriano-Souza et al., 2010Cypriano-Souza AL, Fernández GP, Lima-Rosa CAV, Engel MH and Bonatto SL (2010) Microsatellite genetic characterization of the humpback whale (Megaptera novaeangliae) Breeding Ground off Brazil (Breeding Stock A). J Hered 101:189-200., 2017Cypriano-Souza AL, Engel MH, Caballero S, Olavarría C, Flórez-González L, Capella J, Steel D, Sremba A, Aguayo A, Thiele D, et al. (2017) Genetic differentiation between humpback whales (Megaptera novaeangliae) from Atlantic and Pacific breeding grounds of South America. Mar Mamm Sci 33:457-479.). This high genetic diversity is in agreement with other breeding grounds studied in the Southern Hemisphere for both nuclear and mitochondrial markers (e.g. Valsecchi et al., 2002Valsecchi E, Hale P, Corkeron P and Amos W (2002) Social structure in migrating humpback whales (Megaptera novaeangliae). Mol Ecol 11:507-518.; Garrigue et al., 2004Garrigue C, Dodemont R, Steel D and Baker CS (2004) Organismal and ‘gametic’ capture-recapture using microsatellite genotyping confirm low abundance and reproductive autonomy of humpback whales on the wintering grounds of New Caledonia. Mar Ecol Progr Ser 274:251-262.; Pomilla and Rosenbaum, 2006Pomilla C and Rosenbaum HC (2006) Estimates of relatedness in groups of humpback whales (Megaptera novaeangliae) on two wintering grounds of Southern Hemisphere. Mol Ecol 15:2541-2555.; Olavarría et al., 2007Olavarría C, Baker CS, Garrigue C, Poole M, Hauser N, Caballero S, Flórez-González L, Brasseur M, Bannister J, Capella J, et al. (2007) Population structure of humpback whales throughout the South Pacific and the origin of the eastern Polynesian breeding grounds. Mar Ecol Prog Ser 330:257-268.; Rosenbaum et al., 2009Rosenbaum HC, Pomilla C, Mendez M, Leslie MS, Best PB, Findlay KP, Minton G, Ersts PJ, Collins T, Engel MH, et al. (2009) Population structure of humpback whales from their breeding grounds in the South Atlantic and Indian Oceans. PLoS One 4:e7318.; Cypriano-Souza et al., 2017Cypriano-Souza AL, Engel MH, Caballero S, Olavarría C, Flórez-González L, Capella J, Steel D, Sremba A, Aguayo A, Thiele D, et al. (2017) Genetic differentiation between humpback whales (Megaptera novaeangliae) from Atlantic and Pacific breeding grounds of South America. Mar Mamm Sci 33:457-479.). Nevertheless, in the Southwestern Atlantic population, as well as most other humpback populations, severe reductions of their historical size by commercial whaling are well documented. The lowest number reached for breeding stock A was in the late 1950s, when only around 500 individuals (95% CI = 152 to 3,687) were estimated for this population (Zerbini et al., 2011bZerbini AN, Ward EJ, Kinas PG, Engel MH and Andriolo A (2011b) A Bayesian assessment of the conservation status of humpback whales (Megaptera novaeangliae) in the western South Atlantic Ocean. J Cetac Res Manage 3:131-144.). However, our previous study did not detect any significant signal of a genetic bottleneck in this population (Cypriano-Souza et al., 2010Cypriano-Souza AL, Fernández GP, Lima-Rosa CAV, Engel MH and Bonatto SL (2010) Microsatellite genetic characterization of the humpback whale (Megaptera novaeangliae) Breeding Ground off Brazil (Breeding Stock A). J Hered 101:189-200.), using three standard methods: heterozygosity excess (Cornuet and Luikart, 1996Cornuet JM and Luikart G (1996) Description and power analysis of two tests for detecting recent population bottlenecks from allele frequency data. Genetics 144:2001-2014.), mode-shift (Luikart et al., 1998Luikart G, Allendorf FW, Cornuet JM and Sherwin WB (1998) Distortion of allele frequency distributions provides a test for recent population bottlenecks. J Hered 89:238-247.) and M-ratio tests (Garza and Williamson, 2001Garza JC and Williamson EG (2001) Detection of reduced population size using data from microsatellite loci. Mol Ecol 10:305-318.). That result was corroborated here with an extended data set and an ABC approach, in which by far the best supported scenario was a constant population compared with those in which a population experienced a single size change (expansion or bottleneck) or a bottleneck during the commercial whaling (between 2 and 8 generations ago) followed by an expansion (Figure 2).

As discussed previously, these results are consistent with the hypothesis (Amos, 1996Amos B (1996) Levels of genetic variability in cetacean populations have probably changed little as a result of human activities. Rep Int Whaling Comm 46:657-658.) that the genetic bottleneck caused by commercial whaling was not strong enough to have left a significant signal in the BSA population (Engel et al., 2008Engel MH, Fagundes NJR, Rosenbaum HC, Leslie MS, Ott PH, Schmitt R, Secchi E, Dalla Rosa L and Bonatto SL (2008) Mitochondrial DNA diversity of the Southwestern Atlantic humpback whale (Megaptera novaeangliae) breeding area off Brazil, and the potential connections to Antartic feeding areas. Conserv Genet 9:1253-1262.; Cypriano-Souza et al., 2010Cypriano-Souza AL, Fernández GP, Lima-Rosa CAV, Engel MH and Bonatto SL (2010) Microsatellite genetic characterization of the humpback whale (Megaptera novaeangliae) Breeding Ground off Brazil (Breeding Stock A). J Hered 101:189-200.). The magnitude of the genetic bottleneck is related to its duration and the minimum absolute size of the population during the bottleneck (Frankham et al., 2002Frankham R, Ballou JD and Briscoe DA (2002) Introduction to Conservation Genetics. Cambridge University Press, Cambridge, 617 p.). In this population, large scale whaling lasted for only about four generations, assuming that the overexploitation of this stock was in the period between 1904 and 1967 (Paiva and Grangeiro, 1970Paiva MP and Grangeiro BF (1970) Investigations on the whaling seasons 1964-1967, off the northeastern coast of Brazil. Arq Ciênc Mar 10:111-126.) and a generation time of 18 years, taking into account the range between 12 and 24 years estimated for humpback whales (Chittleborough, 1965Chittleborough RG (1965) Dynamics of two populations of the humpback whale, Megaptera novaeangllae (Borowski). Aust J Mar Freshw Res 16:33-128.; Roman and Palumbi, 2003Roman J and Palumbi S (2003) Whales before whaling in North Atlantic. Science 301:508-510.). In addition, the minimum absolute population size reached was relatively large (N_min = 500 individuals in the late 1950s) for the BSA population (Zerbini et al., 2011bZerbini AN, Ward EJ, Kinas PG, Engel MH and Andriolo A (2011b) A Bayesian assessment of the conservation status of humpback whales (Megaptera novaeangliae) in the western South Atlantic Ocean. J Cetac Res Manage 3:131-144.). Therefore, fewer generations with a not so small absolute effective population size should have left only weak genetic bottleneck signals and are, therefore, more difficult to detect. However, this estimation based on catch records did not incorporate missing whaling records between 1929 and 1946, a period in which the catch records in the breeding grounds are incomplete, producing likely biased estimates of depletion levels for this population (Morais et al., 2017Morais IOB, Danilewicz D, Zerbini AN, Edmundson W, Hart IB and Bortolotto GA (2017) From the southern right whale hunting decline to the humpback whaling expansion: A review of whale catch records in the tropical western South Atlantic Ocean. Mammal Rev 47:11-23.).

Recently, Phillips et al. (2012)Phillips CD, Hoffman JI, George JC, Suydam RS, Huebinger RM, Bickham JW and Patton JC (2012) Molecular insights into the historic demography of bowhead whales: understanding the evolutionary basis of contemporary management practices. Ecol Evol 3:18-37. showed a similar result with an ABC analysis for the bowhead whales (Balaena mysticetus), in which a bottleneck scenario was also not supported. In contrast, a recent ABC analysis for the Antarctic fur seal (Arcthocephalus gazella) supported a bottleneck scenario, although they have not detected a bottleneck using standard tests (Hoffman et al., 2011Hoffman JI, Grant SM, Forcada J and Phillips CD (2011) Bayesian inference of a historical bottleneck in a heavily exploited marine mammal. Mol Ecol 20:3989-4008.). These different results were expected given the contrasting values for the two key parameters discussed above between the bowhead whale and the Antarctic fur seal: the generation length of the former was estimated ~50 years and for the latter ~10 years, while the minimum population size during the bottleneck for the former was around 1,000 individuals and for the latter it was as low as ~30-60 individuals (Phillips et al., 2012Phillips CD, Hoffman JI, George JC, Suydam RS, Huebinger RM, Bickham JW and Patton JC (2012) Molecular insights into the historic demography of bowhead whales: understanding the evolutionary basis of contemporary management practices. Ecol Evol 3:18-37.). Interestingly, the inclusion of ancient samples may importantly increase the power to detect recent bottlenecks, as demonstrated by the study with the eastern Pacific gray whales (Eschrichtius robustus) (Alter et al., 2012Alter SE, Newsome SD and Palumbi SR (2012) Prewhaling genetic diversity and population ecology in eastern pacific grey whales: insights from ancient DNA and stable isotopes. PLoS One 7:e35039.).

Although the methods used here assumed closed population with discrete generations (no generation overlap), random mating and equal contribution of individuals to the next generation, these assumptions are rarely completely satisfied in natural populations. The humpback whale is a long-lived species with overlapping generations, and some migration between breeding grounds in the Southern Hemisphere has been documented (Rosenbaum et al., 2009Rosenbaum HC, Pomilla C, Mendez M, Leslie MS, Best PB, Findlay KP, Minton G, Ersts PJ, Collins T, Engel MH, et al. (2009) Population structure of humpback whales from their breeding grounds in the South Atlantic and Indian Oceans. PLoS One 4:e7318.). However, a recent study indicates that single-sample estimators of contemporary N_e based on linkage disequilibrium were not affected significantly with migration rates up to approximately 5–10% (Waples and England, 2011Waples RS and England PR (2011) Estimating contemporary effective population size on the basis of linkage disequilibrium in the face of migration. Genetics 189:633-644.). Indeed, the migration rates between the Atlantic and Pacific breeding grounds of South America were estimated to be lower than the above limits (Cypriano-Souza et al., 2017Cypriano-Souza AL, Engel MH, Caballero S, Olavarría C, Flórez-González L, Capella J, Steel D, Sremba A, Aguayo A, Thiele D, et al. (2017) Genetic differentiation between humpback whales (Megaptera novaeangliae) from Atlantic and Pacific breeding grounds of South America. Mar Mamm Sci 33:457-479.). Likewise, low migration rates based on mtDNA data have been estimated between humpbacks from Brazil and from breeding grounds in the Southeastern Atlantic Ocean (H.C. Rosenbaum, personal communication). The humpback whale is an age-structured species, and our estimates based on mixed-age samples reflect the effective size per generation (N_e), but these estimates are approximately equal to population N_e when the sample includes as many cohorts as there are in a generation (Waples et al., 2014Waples RS and Antao T (2014) Intermittent breeding and constraints on litter size: Consequences for effective population size per generation (Ne) and per reproductive cycle (Nb). Evolution 68:1722-1734.). As we sampled only mature adults from nine different breeding seasons, the number of cohorts in this sample is lower than the generation length. However, our estimates should be fairly robust, albeit perhaps slightly lower, since the species is long-lived and has intermittent breeding (Waples and Antao, 2014Waples RS, Antao T and Luikart G (2014) Effects of overlapping generations on linkage disequilibrium estimates of effective population size. Genetics 197:769-780.).

Our N_e estimates with NeEstimator and DIYABC (point estimates 1,078 and 4,170 individuals, respectively) differed significantly. These differences can be explained mostly because these methods are expected to estimate N_e on different periods. The estimator from NeEstimator uses the amount of linkage disequilibrium within a population and is specifically designed to estimate N_e from the parental generation of the sample. In contrast, the N_e inferred from the ABC approach, considering the constant population scenario, is a long-term (that extends well before the whaling period) population size estimator, that represented the weighted harmonic mean of population sizes over 4N_e generations.

The most recent contemporary abundance estimates of the Brazilian humpback whale population, derived from aerial surveys that covered the entire stock range, estimated 6,404 individuals (95% CI = 5,085–8,068) in 2005, 7,689 individuals (95% CI = 6,585–8,931) in 2008, 8,652 individuals (95% C.I. = 7,696–9,682) in 2011, and 12,123 individuals (95% C.I. = 10,811–13,531) in 2015 (Andriolo et al., 2010Andriolo A, Kinas PG, Engel MH and Martins CCA (2010) Humpback whale population estimates and distribution along the Brazilian breeding ground. Endanger Species Res 11:233-243.; Pavanato et al., 2017Pavanato HJ, Wedekin LL, Guilherme-Silveira FR, Engel MH and Kinas PG (2017) Estimating humpback whale abundance using hierarchical distance sampling. Ecol Modell 358:10-18.). However, recent abundance estimates derived from ship surveys estimated 16,410 individuals (95% C.I. = 10,563–25,495) in 2008 (covered the total population range), and 19,429 individuals (95% C.I. = 15,958–23,654) in 2012, which were about 50% higher than that of the aerial surveys (Bortolotto et al., 2016aBortolotto GA, Danilewicz D, Andriolo A, Secchi ER and Zerbini AN (2016a) Whale, whale, everywhere: Increasing abundance of Western South Atlantic Humpback whales (Megaptera novaeangliae) in their wintering grounds. PLoS One 11:e0164596.). The difference between aerial and ship abundance estimates can be explained mainly by two sources of bias (underestimated group sizes and perception bias) of the first methodology, which may bias downwards the aerial abundance estimates. Therefore, assuming that our census size (N_c) estimated by the NeEstimator, between around 2,600 and 6,800, corresponds to the parental generation of our sample (collected between 1999 and 2007), which given the uncertainty in the generation time would roughly correspond to the years between around 1980 and 1990. These values are broadly compatible with the abundance ship surveys extrapolated to the past using the growth rate of 7.4% per annum (Ward et al., 2011Ward E, Zerbini AN, Kinas PG, Engel MH and Andriolo A (2011) Estimates of population growth rates of humpback whales (Megaptera novaeangliae) in the wintering grounds off the coast of Brazil (Breeding Stock A). J Cetac Res Manage 3:145-149.).

The study on historical (pre-whaling) abundance of the stock A based on catch records using a Bayesian statistical method estimated the population size to nearly 24,700 individuals (95% CI = 22,804-31,220) before exploitation by modern whaling (Zerbini et al., 2011bZerbini AN, Ward EJ, Kinas PG, Engel MH and Andriolo A (2011b) A Bayesian assessment of the conservation status of humpback whales (Megaptera novaeangliae) in the western South Atlantic Ocean. J Cetac Res Manage 3:131-144.). Our point estimate for the long term N_c (~15,000) using the ABC approach was smaller than the pre-whaling abundance cited above, although the confidence intervals widely overlap that estimate. Furthermore, it is compatible with the most representative abundance estimate of approximately 16,000 humpback whales derived from shipboard survey in 2008 (Bortolotto et al., 2016aBortolotto GA, Danilewicz D, Andriolo A, Secchi ER and Zerbini AN (2016a) Whale, whale, everywhere: Increasing abundance of Western South Atlantic Humpback whales (Megaptera novaeangliae) in their wintering grounds. PLoS One 11:e0164596.). However, our results present broad confidence intervals usually derived from large uncertainties of several parameters, such as generation time, mutation rate, or the relation between N_c and N_e. Consequently, more loci, more realistic scenarios (non-instantaneous population growth, gene flow, etc.) and methods are necessary to better estimate the demographic history of this population.

Overall, our results corroborate previous studies that have found high genetic diversity in the humpback whale population wintering off the Brazilian coast and no statistically significant reduction in its genetic diversity caused by modern whaling (Engel et al., 2008Engel MH, Fagundes NJR, Rosenbaum HC, Leslie MS, Ott PH, Schmitt R, Secchi E, Dalla Rosa L and Bonatto SL (2008) Mitochondrial DNA diversity of the Southwestern Atlantic humpback whale (Megaptera novaeangliae) breeding area off Brazil, and the potential connections to Antartic feeding areas. Conserv Genet 9:1253-1262.; Cypriano-Souza et al., 2010Cypriano-Souza AL, Fernández GP, Lima-Rosa CAV, Engel MH and Bonatto SL (2010) Microsatellite genetic characterization of the humpback whale (Megaptera novaeangliae) Breeding Ground off Brazil (Breeding Stock A). J Hered 101:189-200.). Compatible with that, and estimated here for the first time, the N_e of the Southwestern Atlantic Ocean humpback whale population is relatively large. It has been suggested that the short-term minimum viable population size is N_e > 50 and the long-term minimum viable population size is N_e > 500 (Franklin and Frankham, 1998Franklin IR and Frankham R (1998) How large must populations be to retain evolutionary potential? An Conserv 1:69-70.). Therefore, the contemporary N_e estimates of the Brazilian humpback population obtained here were above of these limits, suggesting good protection for its evolutionary future. However, we suggest that similar population size estimates should be carried out every 12 to 24 years (one generation) in order to obtain comparable N_e estimates and to monitor this population. To better accomplish this goal, future studies should attempt to reduce uncertainties of several key parameters, for example increasing the number of loci.

Acknowledgments

This work was supported by Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) [to A.L.C.-S.]; Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) [to S.L.B.]; Fundação de Amparo à Pesquisa do Estado do Rio Grande do Sul (FAPERGS) [to S.L.B.]; Instituto Chico Mendes de Conservação da Biodiversidade/Ministério do Meio Ambiente (ICMBIO/MMA); and Petróleo Brasileiro S.A (PETROBRAS) [to Instituto Baleia Jubarte]. Biopsy samples were collected off Brazil under permit SISBIO 21489-1. We thank everyone from the staff of Instituto Baleia Jubarte involved in biopsy sampling and in the collection of samples from whales stranded, especially Milton Marcondes for the organization and shipment of the samples. We also thank the colleagues of the Laboratório de Biologia Genômica e Molecular/PUCRS for their help in lab activities, in special Cladinara Sarturi for laboratory assistance. We are also grateful to Taran Grant for his suggestions on an earlier version of this paper. Special thanks are to Carlos Olavarria and an anonymous reviewer for their helpful comments and suggestions on the original version of the manuscript.

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Pretto DJ, Andrade MCM, Oliveira JM and Oliveira MGA (2009) First record of a humpback whale, Megaptera novaeangliae (Borowski, 1781), stranding in Pará State, Northern coast of Brazil. Braz J Biol 69:1207-1208.
Rice WR (1989) Analyzing table of statistical tests. Evolution 43:223-225.
Roman J and Palumbi S (2003) Whales before whaling in North Atlantic. Science 301:508-510.
Rooney AP, Honeycutt RL, Davis SK and Derr JN (1999) Evaluating a putative bottleneck in a population of bowhead whales from patterns of microsatellite diversity and genetic disequilibria. J Mol Evol 49:682-690.
Rooney AP, Honeycutt RL and Derr JN (2001) Historical population size change of bowhead whales inferred from DNA sequence polymorphism data. Evolution 55:1678-1685.
Rosenbaum HC, Pomilla C, Mendez M, Leslie MS, Best PB, Findlay KP, Minton G, Ersts PJ, Collins T, Engel MH, et al. (2009) Population structure of humpback whales from their breeding grounds in the South Atlantic and Indian Oceans. PLoS One 4:e7318.
Ruegg KC, Anderson EC, Baker CS, Vant M, Jackson JA and Palumbi SR (2010) Are Antarctic minke whales unusually abundant because of 20th century whaling? Mol Ecol. 19:281-291.
Ruegg KC, Rosenbaum HC, Anderson EC, Engel MH, Rothchild A, Baker CS and Palumbi SR (2013) Long-term population size of the North Atlantic humpback whale within the context of worldwide population structure. Conserv Genet 14:103-114.
Schwartz MK, Tallmon DA and Luikart G (1998) Review of DNA-based census and effective population size estimators. An Conserv 1:293-299.
Schlötterer C, Amos B and Tautz D (1991) Conservation of polymorphic simple sequence loci in cetacean species. Nature 354:63-65.
Tønnessen JN and Johnsen AO (1982) The History of Modern Whaling. University of California Press, Berkeley, 755 p.
Valsecchi E and Amos W (1996) Microsatellite markers for the study of cetacean populations. Mol Ecol 5:151-156.
Valsecchi E, Hale P, Corkeron P and Amos W (2002) Social structure in migrating humpback whales (Megaptera novaeangliae). Mol Ecol 11:507-518.
Van Oosterhout C, Hutchinson WF, Wills DPM and Shipley P (2004) MICRO-CHECKER: software for identifying and correcting genotyping errors in microsatellite data. Mol Ecol Notes 4:535-538.
Waldick RC, Kraus S, Brown M and White BN (2002) Evaluating the effects of historic bottleneck events: An assessment of microsatellite variability in the endangered North Atlantic right whale. Mol Ecol 11:2241-2249.
Waples RS (2005) Genetic estimates of contemporary effective population size: To what time periods do the estimates apply? Mol Ecol 14:3335-3352.
Waples RS (2006) Evaluation of a genetic method for estimating contemporary population size in cetaceans based on linkage disequilibrium. Paper SC/58/AWMP2. International Whaling Commission Scientific Committee, St. Kitts, 12 p.
Waples RS and Antao T (2014) Intermittent breeding and constraints on litter size: Consequences for effective population size per generation (Ne) and per reproductive cycle (Nb). Evolution 68:1722-1734.
Waples RS and England PR (2011) Estimating contemporary effective population size on the basis of linkage disequilibrium in the face of migration. Genetics 189:633-644.
Waples RS, Antao T and Luikart G (2014) Effects of overlapping generations on linkage disequilibrium estimates of effective population size. Genetics 197:769-780.
Ward E, Zerbini AN, Kinas PG, Engel MH and Andriolo A (2011) Estimates of population growth rates of humpback whales (Megaptera novaeangliae) in the wintering grounds off the coast of Brazil (Breeding Stock A). J Cetac Res Manage 3:145-149.
Wedekin LL, Rossi-Santos M, Baracho C, Cypriano-Souza AL and Simões-Lopes PC (2014) Cetacean records along a coastal-offshore gradient in the Vitória-Trindade Chain, western South Atlantic Ocean. Braz J Biol 74:137-144.
Weir BS and Cockerham CC (1984) Estimating F-statistics for the analysis of population structure. Evolution 38:1358-1370.
Williamson GR (1975) Minke whales off Brazil. Sci Rep Whales Res Inst 27:37-59.
Whittaker JC, Harbord RM, Boxall N, Mackay I, Dawson G and Sibly RM (2003) Likelihood-based estimation of microsatellite mutation rates. Genetics 164:781-787.
Yablokov AV, Zemsky VA, Mikhalev YA, Tornosov VV and Berzin AA (1998) Data on Soviet whaling in the Antarctic in 1947-1972 (population aspects). Russ J Ecol 29:38-42.
Zerbini AN, Andriolo A, Heide-Jorgensen MP, Pizzorno JL, Maia YG, VanBlaricom GR, DeMaster DP, Simões-Lopes PC, Moreira S and Bethlem C (2006) Satellite-monitored movements of humpback whales Megaptera novaeangliae in the Southwest Atlantic Ocean. Mar Ecol Prog Ser 313:295-304.
Zerbini AN, Andriolo A, Heide-Jorgensen MP, Moreira S, Pizzorno JL, Maia YG, VanBlaricom G and DeMaster DP (2011a) Migration and summer destinations of humpback whales (Megaptera novaeangliae) in the western South Atlantic Ocean. J Cetac Res Manage 3:113-118.
Zerbini AN, Ward EJ, Kinas PG, Engel MH and Andriolo A (2011b) A Bayesian assessment of the conservation status of humpback whales (Megaptera novaeangliae) in the western South Atlantic Ocean. J Cetac Res Manage 3:131-144.

Associate Editor: Loreta B. Freitas

Publication Dates

Publication in this collection
2018

History

Received
03 Mar 2017
Accepted
01 Aug 2017

License information: This is an open-access article distributed under the terms of the Creative Commons Attribution License (type CC-BY), which permits unrestricted use, distribution and reproduction in any medium, provided the original article is properly cited.

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[81] Zerbini AN, Andriolo A, Heide-Jorgensen MP, Moreira S, Pizzorno JL, Maia YG, VanBlaricom G and DeMaster DP (2011a) Migration and summer destinations of humpback whales (Megaptera novaeangliae) in the western South Atlantic Ocean. J Cetac Res Manage 3:113-118.

[82] Zerbini AN, Ward EJ, Kinas PG, Engel MH and Andriolo A (2011b) A Bayesian assessment of the conservation status of humpback whales (Megaptera novaeangliae) in the western South Atlantic Ocean. J Cetac Res Manage 3:131-144.

Locus	Rep	Allele range	K	H _O	H _E	F _IS
GATA 28	4	143-203	15	0.626	0.612	- 0.022
GATA 53	4	231-287	14	0.791	0.835	0.053
GATA 417	4	186-280	18	0.923	0.909	- 0.016
199/200	2	102-118	8	0.567	0.549	- 0.034
417/418	2	178-204	11	0.754	0.809	0.068
464/465	2	130-152	10	0.587	0.610	0.038
EV1Pm	2	121-129	5	0.553	0.532	- 0.040
EV37Mn	2	192-224	17	0.900	0.923	0.026
EV94Mn	2	201-221	11	0.808	0.817	0.012
EV96Mn	2	183-215	17	0.854	0.866	0.014

Scenario/Parameter	Minimum	Maximum
Scenario 1
Ne	10	30,000
Scenario 2
Ne2	10	300
Na2	5,000	30,000
t	2	10
Scenario 3
Ne3	1,000	5,000
Na3	10	300
t	2	10
Scenario 4
Ne4	1,000	5,000
Nb	10	300
Na4	5,000	30,000
t1 ^* * t2 > t1	2	10
t2 ^* * t2 > t1	2	10

Brasil