Michael T. Clegg

Plant population genetics, breeding, and genetic resources

A resource for students and research workers in population genetics, molecular evolution, evolutionary biology, ecological genetics, forestry and crop improvement.

Relative rates of nucleotide substitution at the rbcL locus of monocotyledonous plants.

SummaryWe subjected 35 rbcL nucleotide sequences from monocotyledonous taxa to maximum likelihood relative rate tests and estimated relative differences in rates of nucleotide substitution between groups of sequences without relying on knowledge of divergence times between taxa. Rate tests revealed that there is a hierarchy of substitution rate at the rbcL locus within the monocots. Among the taxa analyzed the grasses have the most rapid substitution rate; they are followed in rate by the Orchidales, the Liliales, the Bromeliales, and the Arecales. The overall substitution rate for the rbcL locus of grasses is over 5 times the substitution rate in the rbcL of the palms. The substitution rate at the third codon positions in the rbcL of the grasses is over 8 times the third position rate in the palms. The pattern of rate variation is consistent with the generation-time-effect hypothesis. Heterogenous rates of substitution have important implications for phylogenetic reconstruction.

Measuring Plant Mating Systems

Research in evolutionary genetics can be broadly classified into three major problem areas: the study of adaptation, the measurement and description of variation, and the study of the processes of genetic transmission at the population level. When considering the problem of genetic transmission at the population level, one must recognize that the process is statistical because it is a property of collections of individuals and the process is necessarily dynamic. Moreover, genetic transmission is mediated through the pattern of matings in a population because mating forms the essential link between generations. Consequently, virtually all investigations of the dynamics of genetic change are concerned, either directly or indirectly, with the mating process. For this reason, the random mating assumption of the Hardy-Weinberg theorem plays a central role in the theory of population genetics. The Hardy-Weinberg theorem can, however, rarely be applied to plant populations (and to many animal populations as well) because the key assumption of random mating is unlikely to be satisfied. Indeed, plants exhibit a wide variety of mating structures including (a) regular systems of inbreeding and frequently self-fertilization; (b) negative assortative mating due to various kinds of incompatibility systems; and (c) effective inbreeding due to the clustering of related individuals within a small neighborhood. Despite this complexity of mating systems, the problem of specifying the process of genetic transmission at the population level remains paramount. Traditional methods of mating-system assessment have been based on the anal-

A chloroplast DNA mutational hotspot and gene conversion in a noncoding region near rbcL in the grass family (Poaceae).

The noncoding DNA region of the chloroplast genome, flanked by the genes rbcL and psaI (ORF36), has been sequenced for seven species of the grass family (Poaceae). This region had previously been observed as a hotspot area for length mutations. Sequence comparison reveals that short duplications, probably resulting from slipped-strand mispairing, account for many small length differences between sequences but that major mutational hotspots are localized in three small areas, two of which show potential secondary structure. Mutation in one of these hotspots appears to be a result of more complex recombination events. All seven species contain a pseudogene for rpl23 and evidence is presented that this pseudogene is being maintained by gene conversion with the functional gene. Different transition/transversion biases and AT contents between the pseudogene and the surrounding noncoding sequences are noted. In the subfamily Panicoideae there is a deletion in which almost 1 kb of ancestral sequence, including the 3′ end of the rpl23 pseudogene, has been replaced by a non-homologous 60-base sequence of unknown origin. Two other deletions of almost the same region have occurred in the grass family. The deleted noncoding region has mutational and compositional properties similar to the rbcL coding sequence and the rpl23 pseudogene. The three independent deletions, as well as the pattern of mutation in the localized hotspots, indicate that such noncoding DNA may be misleading for studies of phylogenetic inference.

Distinct geographic patterns of genetic diversity are maintained in wild barley (Hordeum vulgare ssp. spontaneum) despite migration.

Mutations arise in a single individual and at a single point in time and space. The geographic distribution of mutations reflects both historical population size and frequency of migration. We employ coalescence-based methods to coestimate effective population size, frequency of migration, and level of recombination compatible with observed genealogical relationships in sequence data from nine nuclear genes in wild barley (Hordeum vulgare ssp. spontaneum), a highly self-fertilizing grass species. In self-fertilizing plants, gamete dispersal is severely limited; dissemination occurs primarily through seed dispersal. Also, heterozygosity is greatly reduced, which renders recombination less effective at randomizing genetic variation and causes larger portions of the genome to trace a similar history. Despite these predicted effects of this mating system, the majority of loci show evidence of recombination. Levels of nucleotide variation and the patterns of geographic distribution of mutations in wild barley are highly heterogeneous across loci. Two of the nine sampled loci maintain highly diverged, geographic region-specific suites of mutations. Two additional loci include region-specific haplotypes with a much shallower coalescence. Despite inbreeding, sessile growth habit, and the observation of geographic structure at almost half of sampled loci, parametric estimates of migration suggest that seed dispersal is sufficient for migration across the ≈3,500-km range of the species. Recurrent migration is also evident based on the geographic distribution of mutational variation at some loci. At one locus a single haplotype has spread rapidly enough to occur, unmodified by mutation, across the range of the species.

Evolutionary Dynamics of the DNA-Binding Domains in Putative R2R3-MYB Genes Identified from Rice Subspecies indica and japonica Genomes

The molecular evolution of the R2R3-MYB gene family is of great interest because it is one of the most important transcription factor gene families in the plant kingdom. Comparative analyses of a gene family may reveal important adaptive changes at the protein level and thereby provide insights that relate structure to function. We have performed a range of comparative and bioinformatics analyses on R2R3-MYB genes identified from the rice (Oryza sativa subsp. japonica and indica) and Arabidopsis genome sequences. The study provides an initial framework to investigate how different evolutionary lineages in a gene family evolve new functions. Our results reveal a remarkable excess of non-synonymous substitutions, an indication of adaptive selection on protein structure that occurred during the evolution of both helix1 and helix2 of rice R2R3-MYB DNA-binding domains. These flexible α-helix regions associated with high frequencies of excess non-synonymous substitutions may play critical roles in the characteristic packing of R2R3-MYB DNA-binding domains and thereby modify the protein-DNA interaction process resulting in the recognition of novel DNA-binding sites. Furthermore, a co-evolutionary pattern is found between the second α-helix of the R2 domain and the second α-helix of the R3 domain by examining all the possible α-helix pairings in both the R2 and R3 domains. This points to the functional importance of pairing interactions between related secondary structures.

Neighboring base composition is strongly correlated with base substitution bias in a region of the chloroplast genome.

Nucleotide sequence from a region of the chloroplast genome is presented for 12 species spanning four subfamilies of the grass family. The region contains the coding sequence for the rbcL gene and the intergenic spacer between the gene coding the large subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase rbcL and the photosystem I gene psal. This intergenic spacer contains a pseudogene for rpl23 as well as two noncoding segments with different A+T contents. Using the sequence of rbcL a chloroplast phylogeny of this family was constructed by parsimony. Variable sites of the two noncoding segments were traced onto the phylogeny to study the dynamics of base substitution. This was also performed for the fourfold-degenerate sites of the rbcL gene. A wide variation in transversion/transition is observed between the two noncoding segments and between the noncoding DNA and the fourfold-degenerate sites of rbcL This variation is correlated with regional A+T content. As regional A+T content decreases, the ratio of transversions to transitions also decreases. Substitutions were then scored in relation to neighboring base composition. The composition of the two bases immediately flanking each substitution is highly correlated with the transversion/transition bias. When both the 5′ and 3′ flanking bases are an A or a T, transversions are observed 2.2 times as frequently as transitions. When either or both neighbors are a C or a G, the opposite trend is found; transitions are observed 1.5 times more frequently than transversions.

Avocado cellulase: nucleotide sequence of a putative full-length cDNA clone and evidence for a small gene family

A cDNA library was prepared from ripe avocado fruit (Persea americana Mill. cv. Hass) and screened for clones hybridizing to a 600 bp cDNA clone (pAV5) coding for avocado fruit cellulase. This screening led to the isolation of a clone (pAV363) containing a 2021 nucleotide transcribed sequence and an approximately 150 nucleotide poly(A) tail. Hybridization of pAV363 to a northern blot shows that the length of the homologous message is approximately 2.2 kb. The nucleotide sequence of this putative full-length mRNA clone contains an open reading frame of 1482 nucleotides which codes for a polypeptide of 54.1 kD. The deduced amino acid composition compares favorably with the amino acid composition of native avocado cellulase determined by amino acid analysis. Southern blot analysis of Hind III and Eco RI endonuclease digested genomic DNA indicates a small family of cellulase genes.

The influence of specific neighboring bases on substitution bias in noncoding regions of the plant chloroplast genome.

Abstract. Substitutions occurring in noncoding sequences of the plant chloroplast genome violate the independence of sites that is assumed by substitution models in molecular evolution. The probability that a substitution at a site is a transversion, as opposed to a transition, increases significantly with increasing A + T content of the two adjacent nucleotides. In the present study, this dependency of substitutions on local context is examined further in a number of noncoding regions from the chloroplast genome of members of the grass family (Poaceae). Two features were examined; the influence of specific neighboring bases, as opposed to the general A + T content, on transversion proportion and an influence on substitutions by nucleotides other than the two immediately adjacent to the site of substitution. In both cases, a significant effect was found. In the case of specific nucleotides, transversion proportion is significantly higher at sites with a pyrimidine immediately 5′ on either strand. Substitutions at sites of the type YNR, where N is the site of substitution, have the highest rate of transversion. This specific effect is secondary to the A + T content effect such that, in terms of proportion of substitutions that are transversions, the nucleotides are ranked T > A > C > G as to their effect when they are immediately 5′ to the site of substitution. In the case of nucleotides other than the immediate neighbors, a significant influence on substitution dynamics is observed in the case where the two neighboring bases are both A and/or T. Thus, substitutions are primarily, but not exclusively, influenced by the composition of the two nucleotides that are immediately adjacent. These results indicate that the pattern of molecular evolution of the plant chloroplast genome is extremely complex as a result of a variety of inter-site dependencies.

Genes that determine flower color: the role of regulatory changes in the evolution of phenotypic adaptations

A central goal of evolutionary genetics is to trace the causal pathway between mutations at particular genes and adaptation at the phenotypic level. The proximate objective is to identify adaptations through the analysis of molecular sequence data from specific candidate genes or their regulatory elements. In this paper, we consider the molecular evolution of floral color in the morning glory genus (Ipomoea) as a model for relating molecular and phenotypic evolution. To begin, flower color variation usually conforms to simple Mendelian transmission, thus facilitating genetic and molecular analyses. Population genetic studies of flower color polymorphisms in the common morning glory (Ipomoea purpurea) have shown that some morphs are subject to complex patterns of selection. Striking differences in floral color and morphology are also associated with speciation in the genus Ipomoea. The molecular bases for these adaptive shifts can be dissected because the biosynthetic pathways that determine floral pigmentation are well understood and many of the genes of flavonoid biosynthesis have been isolated and extensively studied. We present a comparative analysis of the level of gene expression in Ipomoea for several key genes in flavonoid biosynthesis. Specifically we ask: how frequently are adaptive shifts in flower color phenotypes associated with changes in regulation of gene expression versus mutations in structural genes? The results of this study show that most species differences in this crucial phenotype are associated with changes in the regulation of gene expression.