A power-law relationship between population variance and mean abundance, V=aMb, is commonly observed in ecology. Many factors have been proposed to influence ‘b’, such as aggregation degree, growth rate, and reproduction, although the interpretation of the intercept ‘a’ remains elusive. In this study, we estimated the spatial variance-mean relationship of 29 fish species collected from the southern California Current Ecosystem spanning from 1951-2007. We investigated whether Taylor’s exponent ‘b’ is related to life history traits of fishes. In addition, we examined the fishing impacts by comparing exploited versus unexploited species, accounting for life history variation using a general linear model. We found that after removing the influence of mean abundance, all life history traits play a significant role in determining the exponent. Unexploited species with traits related to r-strategy tend to have higher Taylor’s exponent. However, the relationship between the exponents and life history traits of exploited species is much weaker than that of the unexploited species. Our results suggest that fishing may change the exponent of a species through changing their life history traits, such as maximum length and maturation age. Thus, the exploited species exhibited a higher variance in spatial distribution than an unexploited species with the similar abundance and recorded life traits. We also develop an individual-based model to investigate the generating processes of Taylor’s Power Law, and whether age-truncated species have higher Taylor’s exponents. Our model shows that Taylor’s Power Law can be produced through demographic processes. Species with higher directional moving ability behave more aggregated. When reproduction rate increases, our model shows that species have higher average spatial variance but reflecting in Taylor’s intercept instead of exponent. Furthermore, the average spatial variance-mean ratio of exploited species is also reproduced in our model, reflecting the increasing aggregation. Our model suggests species with r-selective traits and suffering age-truncation will have higher spatial variance, but the different mechanisms of change in a and b still needed further studies.