Anotace:
This paper provides an overview of advances in the analysis of the genetic structure of populations, focusing on the evolution of statistical approaches and their applications in conservation genetics. Understanding genetic relationships among populations is crucial for assessing evolutionary processes such as gene flow, genetic drift, and selection, which fundamentally affect genetic diversity over time. Traditionally, studies relied on a limited number of genetic markers and summary statistics; however, the advent of high-throughput genomic technologies has dramatically enhanced both the resolution and accuracy of these analyses. Whole-genome sequencing and dense SNP arrays now provide unprecedented insights into neutral and adaptive variations, enabling fine-scale detection of population subdivisions and historical demographic trends. In parallel, the development of advanced statistical models has refined genetic analyses, allowing for more precise estimations of genetic differentiation, admixture, and ancestral relationships. These innovations are particularly valuable in conservation genetics, where robust assessments are essential for optimising strategies to maintain genetic diversity, identify populations at risk, and mitigate the effects of inbreeding and effective population size decline. Despite these improvements, challenges remain, including computational demands and the need to account for complex demographic histories and selection pressures. Given the continuous evolution of analytical techniques, selecting appropriate methods tailored to specific research questions is critical for producing reliable insights into population structure and effectively guiding conservation efforts. In conclusion, the continuous advancement of genomic analysis tools enhances the ability to study population dynamics in greater detail and supports more effective conservation planning.