Fraser Dylan J, Hansen Michael M, Ostergaard Siri, Tessier Nathalie, Legault Michel, Bernatchez Louis
Department of Biology, Dalhousie University, Halifax, Nova Scotia, Canada B3H 1J1.
Mol Ecol. 2007 Sep;16(18):3866-89. doi: 10.1111/j.1365-294X.2007.03453.x.
Estimation of effective population sizes (N(e)) and temporal gene flow (N(e)m, m) has many implications for understanding population structure in evolutionary and conservation biology. However, comparative studies that gauge the relative performance of N(e), N(e)m or m methods are few. Using temporal genetic data from two salmonid fish population systems with disparate population structure, we (i) evaluated the congruence in estimates and precision of long- and short-term N(e), N(e)m and m from six methods; (ii) explored the effects of metapopulation structure on N(e) estimation in one system with spatiotemporally linked subpopulations, using three approaches; and (iii) determined to what degree interpopulation gene flow was asymmetric over time. We found that long-term N(e) estimates exceeded short-term N(e) within populations by 2-10 times; the two were correlated in the system with temporally stable structure (Atlantic salmon, Salmo salar) but not in the highly dynamic system (brown trout, Salmo trutta). Four temporal methods yielded short-term N(e) estimates within populations that were strongly correlated, and these were higher but more variable within salmon populations than within trout populations. In trout populations, however, these short-term N(e) estimates were always lower when assuming gene flow than when assuming no gene flow. Linkage disequilibrium data generally yielded short-term N(e) estimates of the same magnitude as temporal methods in both systems, but the two were uncorrelated. Correlations between long- and short-term geneflow estimates were inconsistent between methods, and their relative size varied up to eightfold within systems. While asymmetries in gene flow were common in both systems (58-63% of population-pair comparisons), they were only temporally stable in direction within certain salmon population pairs, suggesting that gene flow between particular populations is often intermittent and/or variable. Exploratory metapopulation N(e) analyses in trout demonstrated both the importance of spatial scale in estimating N(e) and the role of gene flow in maintaining genetic variability within subpopulations. Collectively, our results illustrate the utility of comparatively applying N(e), N(e)m and m to (i) tease apart processes implicated in population structure, (ii) assess the degree of continuity in patterns of connectivity between population pairs and (iii) gauge the relative performance of different approaches, such as the influence of population subdivision and gene flow on N(e) estimation. They further reiterate the importance of temporal sampling replication in population genetics, the value of interpreting N(e)or m in light of species biology, and the need to address long-standing assumptions of current N(e), N(e)m or m models more explicitly in future research.
有效种群大小(N(e))和时间基因流(N(e)m,m)的估计对于理解进化生物学和保护生物学中的种群结构具有许多重要意义。然而,评估N(e)、N(e)m或m方法相对性能的比较研究却很少。利用来自两个种群结构不同的鲑科鱼类种群系统的时间遗传数据,我们(i)评估了六种方法对长期和短期N(e)、N(e)m和m的估计一致性和精度;(ii)使用三种方法,探讨了集合种群结构对一个具有时空相连亚种群的系统中N(e)估计的影响;(iii)确定种群间基因流随时间不对称的程度。我们发现,种群内长期N(e)估计值比短期N(e)高出2至10倍;在结构随时间稳定的系统(大西洋鲑,Salmo salar)中,二者具有相关性,但在高度动态的系统(褐鳟,Salmo trutta)中则没有。四种时间方法得出的种群内短期N(e)估计值高度相关,且这些估计值在鲑鱼种群中比在鳟鱼种群中更高但更具变异性。然而,在鳟鱼种群中,假设存在基因流时这些短期N(e)估计值总是低于假设不存在基因流时的值。连锁不平衡数据在两个系统中通常得出与时间方法相同量级的短期N(e)估计值,但二者不相关。长期和短期基因流估计值之间的相关性在不同方法间不一致,且它们在系统内的相对大小变化高达八倍。虽然基因流不对称在两个系统中都很常见(5个种群对比较中的58 - 63%),但仅在某些鲑鱼种群对中方向随时间稳定,这表明特定种群间的基因流通常是间歇性的和/或可变的。对鳟鱼进行的探索性集合种群N(e)分析表明了空间尺度在估计N(e)中的重要性以及基因流在维持亚种群内遗传变异性中的作用。总体而言,我们的结果说明了比较应用N(e)、N(e)m和m的效用在于(i)区分与种群结构相关的过程;(ii)评估种群对间连通性模式的连续程度;(iii)衡量不同方法的相对性能,如种群细分和基因流对N(e)估计的影响。它们进一步重申了种群遗传学中时间抽样重复的重要性、根据物种生物学解释N(e)或m的价值,以及在未来研究中更明确地解决当前N(e)、N(e)m或m模型长期存在的假设的必要性。
