# Synergy from reproductive division of labor and genetic complexity drive   the evolution of sex

**Authors:** Klaus Jaffe

arXiv: 1702.02141 · 2018-04-18

## TL;DR

This study uses computer simulations to explore how reproductive division of labor and genetic complexity interact as a network of factors influencing the evolution of sex, revealing a complex interplay beyond simple models.

## Contribution

It demonstrates that the evolution of sex involves a network of interacting reproductive strategies and genetic factors, emphasizing the roles of diploidy and division of labor.

## Key findings

- Diploidy is essential for the evolution of sex.
- Bisexuality arises in anisogamic diploids with reproductive division of labor.
- Facultative sex is more likely among haploids with assortative mating.

## Abstract

Computer experiments that mirror the evolutionary dynamics of sexual and asexual organisms as they occur in nature, tested features proposed to explain the evolution of sexual recombination. Results show that this evolution is better described as a network of interactions between possible sexual forms, including diploidy, thelytoky, facultative sex, assortation, bisexuality, and division of labor between the sexes, rather than a simple transition from parthenogenesis to sexual recombination. Diploidy was shown to be fundamental for the evolution of sex; bisexual reproduction emerged only among anisogamic diploids with a synergistic division of reproductive labor; and facultative sex was more likely to evolve among haploids practicing assortative mating. Looking at the evolution of sex as a complex system through individual based simulations, explains better the diversity of sexual strategies known to exist in nature, compared to classical analytical models

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Source: https://tomesphere.com/paper/1702.02141