Tetrahymena Macronuclear Genome Mapping: Colinearity of Macronuclear Coassortment Groups and the Micronuclear Map on Chromosome 1L

Tetrahymena Macronuclear Genome Mapping: Colinearity of Macronuclear Coassortment Groups and the Micronuclear Map on Chromosome 1L

Steve Wickert^a, Leslie Nangle^a, Steve Shevel^a, and Eduardo Orias^a
^a Department of Molecular, Cellular, and Developmental Biology, University of California, Santa Barbara, California 93106

Corresponding author: Eduardo Orias, Department of Molecular, Cellular, and Developmental Biology, University of California, Santa Barbara, CA 93106., orias{at}lifesci.lscf.ucsb.edu (E-mail)

Communicating editor: S. L. ALLEN

The genetics of the ciliate Tetrahymena thermophila are richerthan for most other eukaryotic cells, because Tetrahymena possessestwo genomes: a germline (micronuclear) genome that follows aMendelian model of genetic transmission and a somatic (macronuclear)genome, derived from the micronuclear genome by fragmentation,which follows a different genetic transmission model calledphenotypic assortment. While genetic markers in the micronucleusfall into classical linkage groups under meiotic recombinationand segregation, the same markers in the macronucleus fall intocoassortment groups (CAGs) under phenotypic assortment by therandom distribution of MAC chromosome pieces. We set out todetermine whether genomic mapping in the macronucleus by geneticmeans is feasible. To investigate the relationship between themicronuclear map and coassortment groups, we systematicallyplaced into CAGs all of the markers lying on chromosome 1L thatare also found in the macronucleus. Sixteen CAGs were identified,7 of which contain at least two loci. We have concluded thatCAGs represent a fundamental genetic feature of the MAC. TheMIC and MAC maps on 1L are colinear; that is, CAGs consist exclusivelyof markers that map to a continuous segment in a given regionof the micronuclear map, with no intervening markers from otherCAGs. These findings provide a solid foundation for exploitingthe MAC chromosome pieces to build a physical map of the Tetrahymenagenome.

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