| P50 | author | Sarah Otto | Q7422662 |
| P2093 | author name string | N H Barton | |
| P2860 | cites work | Genetic hitchhiking | Q22065923 |
| | EVOLUTION OF SEXRESOLVING THE PARADOX OF SEX AND RECOMBINATION | Q22121995 |
| | The evolutionary advantage of recombination | Q24533419 |
| | Linkage and the limits to natural selection | Q28769449 |
| | Chromosome interactions in Drosophila melanogaster. II. Total fitness. | Q33948889 |
| | Selection, generalized transmission and the evolution of modifier genes. I. The reduction principle | Q33953545 |
| | Natural and sexual selection on many loci | Q33957453 |
| | Do deleterious mutations act synergistically? Metabolic control theory provides a partial answer | Q33960338 |
| | The evolution of recombination: removing the limits to natural selection. | Q33971025 |
| | Attainment of Quasi Linkage Equilibrium When Gene Frequencies Are Changing by Natural Selection | Q33982521 |
| | The mutational load with epistatic gene interactions in fitness | Q33983691 |
| | The Genetic Structure of Natural Populations of DROSOPHILA MELANOGASTER. VII Synergistic Interaction of Spontaneous Mutant Polygenes Controlling Viability. | Q33985716 |
| | Deleterious mutations and the evolution of sexual reproduction | Q34164458 |
| | Test of synergistic interactions among deleterious mutations in bacteria | Q34448329 |
| | Testing for epistasis between deleterious mutations | Q34604153 |
| | Experimental tests of the adaptive significance of sexual recombination | Q34609885 |
| | Genomic mutation rates for lifetime reproductive output and lifespan in Caenorhabditis elegans | Q36105992 |
| | Evolution of recombination in a constant environment | Q36403048 |
| | Deleterious mutations, variable epistatic interactions, and the evolution of recombination. | Q41486670 |
| | Chromosome interactions in Drosophila melanogaster. I. Viability studies. | Q41898379 |
| | The evolution of multilocus systems under weak selection | Q42182701 |
| | Recombination can evolve in large finite populations given selection on sufficient loci. | Q42533089 |
| | Nature of deleterious mutation load in Drosophila. | Q42967314 |
| | Recombination modification in a flucturating environment | Q42974040 |
| | The evolutionary advantage of recombination. II. Individual selection for recombination | Q42974108 |
| | Population Size, Natural Selection and the Genetic Load | Q47401843 |
| | Increased recombination frequencies resulting from directional selection for geotaxis in Drosophila | Q50115982 |
| | Deleterious mutations and the evolution of sex. | Q52583324 |
| | Selection for linkage modification. I. Random mating populations. | Q52969891 |
| | The Response to Artificial Selection Due to Autosomal Genes of Large Effect II. The Effects of Linkage on Limits to Selection in Finite Populations | Q53032183 |
| | TEST OF INTERACTION BETWEEN GENETIC MARKERS THAT AFFECT FITNESS IN ASPERGILLUS NIGER. | Q53246367 |
| | Deleterious mutations as an evolutionary factor: 1. The advantage of recombination | Q56341012 |
| | Selection for recombination in a polygenic model – the mechanism | Q68346852 |
| | Mutation-selection balance and the evolutionary advantage of sex and recombination | Q68904022 |
| | Classification of hypotheses on the advantage of amphimixis | Q70503887 |
| | Selection against harmful mutations in large sexual and asexual populations | Q70563103 |
| | A general model for the evolution of recombination | Q71859154 |
| | Directional selection and the evolution of sex and recombination | Q72912312 |
| | The effect of linkage on limits to artificial selection | Q72951099 |
| | Selection for recombination in small populations | Q77401068 |
| P433 | issue | 4 | |
| P407 | language of work or name | English | Q1860 |
| P304 | page(s) | 2353-2370 | |
| P577 | publication date | 2005-01-31 | |
| P1433 | published in | Genetics | Q3100575 |
| P1476 | title | Evolution of recombination due to random drift | |
| P478 | volume | 169 | |