Abstract

<div><p>The evolutionary fate of an allele ordinarily depends on its contribution to host fitness. Occasionally, however, genetic elements arise that are able to gain a transmission advantage while simultaneously imposing a fitness cost on their hosts. We previously discovered one such element in <em>C. elegans</em> that gains a transmission advantage through a combination of paternal-effect killing and zygotic self-rescue. Here we demonstrate that this element is composed of a sperm-delivered toxin, <em>peel-1</em>, and an embryo-expressed antidote, <em>zeel-1</em>. <em>peel-1</em> and <em>zeel-1</em> are located adjacent to one another in the genome and co-occur in an insertion/deletion polymorphism. <em>peel-1</em> encodes a novel four-pass transmembrane protein that is expressed in sperm and delivered to the embryo via specialized, sperm-specific vesicles. In the absence of <em>zeel-1</em>, sperm-delivered PEEL-1 causes lethal defects in muscle and epidermal tissue at the 2-fold stage of embryogenesis. <em>zeel-1</em> is expressed transiently in the embryo and encodes a novel six-pass transmembrane domain fused to a domain with sequence similarity to <em>zyg-11</em>, a substrate-recognition subunit of an E3 ubiquitin ligase. <em>zeel-1</em> appears to have arisen recently, during an expansion of the <em>zyg-11</em> family, and the transmembrane domain of <em>zeel-</em>1 is required and partially sufficient for antidote activity. Although PEEL-1 and ZEEL-1 normally function in embryos, these proteins can act at other stages as well. When expressed ectopically in adults, PEEL-1 kills a variety of cell types, and ectopic expression of ZEEL-1 rescues these effects. Our results demonstrate that the tight physical linkage between two novel transmembrane proteins has facilitated their co-evolution into an element capable of promoting its own transmission to the detriment of organisms carrying it.</p> </div>