Understanding the key drivers of population cycles can reduce uncertainty in fisheries management. Theoretical studies suggest that population cycles arise from the interactions between external forcing (e.g. environmental variability) and a population’s internal process (e.g. life-history traits). Nonetheless, few empirical studies have explored these underlying mechanisms. To bridge this knowledge gap, we examined the otter trawler catch-per-unit-effort (CPUE) time series (1970-1999) for nine important fishery species, quantifying their CPUE cycles in relation to external and internal processes. The nine species constitute various life histories (represented as fast-to-slow continuum of life histories) and are the main target species in two regions: East China Sea and Taiwan Strait. We hypothesized that 1) species abundance cycles should reflect life-history patterns; e.g., species with slow life histories show relatively long-period cycles as compared to those with fast life histories, 2) regional environments could induce different cyclic patterns between conspecific populations, and 3) cohort resonance (which involves sensitivity to specific time scales of environmental variability that match species maturation ages)would induce short-period cycles on wavelet spectra. We did not find a clear relationship between the species spectral patterns and the fast-slow continuum in life histories. Instead, the power spectral patterns were similar among all species in both regions. There were signs of regional environments and cohort resonance on power spectra in species with fast and slow life histories, confounding the effects of life histories on power spectra. Overall, these results provide evidence on complex interactions of environmental effects and internal processes on fisheries species. For sustainable management, we suggest setting high priority for management for species that exhibited short-period cycles, especially those with signs of cohort resonance.