Analyses of Alternatively Processed Genes in Ciliates Provide Insights into the Origins of Scrambled Genomes and May Provide a Mechanism for Speciation

Chromosome rearrangements occur in a variety of eukaryotic life cycles, including during the development of the somatic macronuclear genome in ciliates. Previous work on the phyllopharyngean ciliate Chilodonella uncinata revealed that macronuclear β-tubulin and protein kinase gene families share alternatively processed germ line segments nested within divergent regions. To study genome evolution in this ciliate further, we characterized two additional alternatively processed gene families from two cryptic species of the ciliate morphospecies C. uncinata: those encoding histidine acid phosphatase protein (Hap) and leishmanolysin family protein (Lei). Analyses of the macronuclear Hap and Lei sequences reveal that each gene family consists of three members in the macronucleus that are marked by identical regions nested among highly divergent regions. Investigation of the micronuclear Hap sequences revealed a complex pattern in which the three macronuclear sequences are derived either from a single micronuclear region or from a combination of this shared region recombined with additional duplicate micronuclear copies of Hap. We propose a model whereby gene scrambling evolves by gene duplication followed by partial and reciprocal degradation of the duplicate sequences. In this model, alternative processing represents an intermediate step in the evolution of scrambled genes. Finally, we speculate on the possible role of genome architecture in speciation in ciliates by describing what might happen if changes in alternatively processed loci occur in subdivided populations.