Linking the evolution of gender variation to floral development

BACKGROUND AND AIMS: In the present review, I have endeavoured to conduct a joint assessment of the thinking underlying the evolutionary genetics of gender polymorphism and the developmental genetics of gender determination. It is my hope, through highlighting the historical development of ideas in two related but somewhat disparate sets of scientific literature, to encourage a synthetic perspective that integrates the two. SCOPE: An overview is provided of various theories on the evolution of sex polymorphism and examples of evidence that has been brought to bear in support of them. Current knowledge on floral development is summarized, with an emphasis on gender variation. Finally, an attempt is made to integrate the two perspectives with the hope that it will encourage future research at the interface. CONCLUSIONS: Evolutionary models of gender evolution have, of necessity, posited genetic effects that are relatively simple in their impacts. Emerging insights from developmental genetics have demonstrated that the underlying reality is a more complex matrix of interacting factors. The study of gender variation in plants is poised for significant advance through the integration of these two perspectives. Bringing genomic tools to bear on population-level processes, we may finally develop a comprehensive perspective on the evolution of floral gender.     

Characterization of the 16S–23S internal transcribed spacer among 34 higher plants: suitability for interspecific plastid transformation

Biomanufacturing by chloroplast transgene expression has the potential to produce significant amounts of biopharmaceuticals, endow plants with novel commercial or humanitarian capabilities, enhance phytoremediation methods and harden plants against adverse environments. Plastid bioengineering exploits the phenomenon of homologous recombination to specifically integrate heterologous sequences into the plastid genome. Previous research suggests the plastid genome 16S–23S internal transcribed spacer provides an advantageous integration site for transgene expression. To characterize the suitability of the 16S–23S region for interspecific recombination, we developed primers against conserved plastid sequences and amplified ∼2.6 kb from 25 plant species. We analyzed the amplicons with nine species from Genbank for homeology, phylogenetic relationships, potential to form chimeric rDNA elements disruptive to translational/replication systems, and the potential number of recombination events for various minimal essential processing segments (MEPS) lengths. Multiple sequence alignment of the 34 species revealed considerable conservation, with identities exceeding 95% among the angiosperms. Substitutions were statistically clustered, generally in noncoding sites, although proposed functional elements such as the OriA region and 3′ terminus of the 16S rRNA exhibited unexpected variation. The nonrandom distribution of substitutions undermines the established, statistical method of estimating the number of recombination initiation sites. This finding is further substantiated by comparing statistical estimates of the number of MEPS sites to a direct count at three different MEPS lengths. We frame this in silico analysis in terms of the potential of the 16S–23S region as a target for interspecific transformation, and describe a ‘primer-to-plastid’ system to rapidly generate species-specific flanking regions for transformation vectors.     

Structure of amplified DNA, analyzed by pulsed field gradient gel electrophoresis

Pulsed field gradient electrophoresis allows the separation of large DNA molecules up to 2,000 kilobases (kb) in length and has the potential to close the resolution gap between standard electrophoresis of DNA molecules (smaller than 50 kb) and standard cytogenetics (larger than 2,000 kb). We have analysed the amplified DNA in four cell lines containing double minute chromosomes (DMs) and two lines containing homogeneously staining regions. The cells were immobilized in agarose blocks, lysed, deproteinized, and the liberated DNA was digested in situ with various restriction endonucleases. Following electrophoretic separation by pulsed field gel electrophoresis, the DNA in the gel was analysed by Southern blotting with appropriate probes for the amplified DNA. We find that the DNA in intact DMs is larger than 1,500 kb. Our results are also compatible with the notion that the DNA in DMs is circular, but this remains to be proven. The amplified segment of wild-type DNA covers more than 550 kb in all lines and possibly up to 2,500 kb in some. We confirm that the repeat unit is heterogeneous in some of the amplicons. In two cell lines, however, with low degrees of gene amplification, we find no evidence for heterogeneity of the repeats up to 750 (Y1-DM) and 800 kb (3T6-R50), respectively. We propose that amplicons start out long and homogeneous and that the heterogeneity in the repeat arises through truncation during further amplification events in which cells with shorter repeats have a selective advantage. Even if the repeats are heterogeneous, however, pulsed field gradient gels can be useful to establish linkage of genes over relatively short chromosomal distances (up to 1,000 kb). We discuss some of the promises and pitfalls of pulsed field gel electrophoresis in the analysis of amplified DNA.     

Low incidence of polyploids and high uniformity of karyotypes displayed by Delphinium (Ranunculaceae) in the Hengduan Mountains region of south‐west China

The chromosome numbers and morphology in 92 populations belonging to 49 species and three varieties in the genus Delphinium L. (Ranunculaceae), mostly from the Hengduan Mountains region of south‐west China, were studied. Forty seven species and three varieties were diploid, with 2n = 16, one species was tetraploid, with 2n = 32, and one species had diploid and tetraploid cytotypes. Three species had B chromosomes, representing the first time the occurrence of B chromosomes has been reported in the genus. The karyotypes of all the diploid species were quite uniform, commonly bimodal, and usually consisted of one pair of large median‐centromeric (m), one pair of large submedian‐centromeric (sm), five pairs of medium‐sized subterminal‐centromeric (st), and one pair of smaller sm (rarely st) chromosomes. The low incidence of polyploids in Delphinium from the Hengduan Mountains region indicates that polyploidy has played a minor role in the speciation of this highly diversified genus in the region. © 2008 The Linnean Society of London, Botanical Journal of the Linnean Society, 2008, 158 , 172–188.     

Chloroplast DNA variation and evolution in the genus Lens Mill

 Chloroplast DNA (cpDNA) restriction site diversity was assessed by 21 enzyme/probe combinations in 30 accessions of six Lens species, including the recently recognized L. lamottei and L. tomentosus. A total of 118 fragments were scored and 26 restriction site mutations were identified. The cpDNA restriction pattern supports circumscribing L. lamottei and L. tomentosus as independent species. The value of the data for reconstructing phylogeny in the genus is discussed. The cpDNA of all 13 accessions of the lentil’s wild progenitor, L. culinaris subsp. orientalis, differed from that of the single lentil cultivars used in this study. This diversity indicates that other populations of this subspecies from Turkey and Syria examined by Mayer and Soltis (1994) are potentially the founder members of lentil. Examination of L. lamottei×L. nigricans hybrids between accessions having different restriction patterns showed paternal plastid inheritance in L. nigricans. Received: 2 July 1996 / Accepted: 19 July 1996     

Postzygotic incompatibilities between the pupfishes, Cyprinodon elegans and Cyprinodon variegatus: hybrid male sterility and sex ratio bias

I examined the intrinsic postzygotic incompatibilities between two pupfishes, Cyprinodon elegans and Cyprinodon variegatus. Laboratory hybridization experiments revealed evidence of strong postzygotic isolation. Male hybrids have very low fertility, and the survival of backcrosses into C. elegans was substantially reduced. In addition, several crosses produced female-biased sex ratios. Crosses involving C. elegans females and C. variegatus males produced only females, and in backcrosses involving hybrid females and C. elegans males, males made up approximately 25% of the offspring. All other crosses produced approximately 50% males. These sex ratios could be explained by genetic incompatibilities that occur, at least in part, on sex chromosomes. Thus, these results provide strong albeit indirect evidence that pupfish have XY chromosomal sex determination. The results of this study provide insight on the evolution of reproductive isolating mechanisms, particularly the role of Haldane's rule and the 'faster-male' theory in taxa lacking well-differentiated sex chromosomes.     

FISH to meiotic pachytene chromosomes of tomato locates the root-knot nematode resistance gene Mi-1 and the acid phosphatase gene Aps-1 near the junction of euchromatin and pericentromeric heterochromatin of chromosome arms 6S and 6L, respectively

 The root-knot nematode resistance gene Mi-1 in tomato has long been thought to be located in the pericentromeric heterochromatin region of the long arm of chromosome 6 because of its very tight genetic linkage (approx. 1 cM) to the markers Aps-1 (Acid phosphatase 1) and yv (yellow virescent). Using Mi-BAC clones and an Aps-1 YAC clone in fluorescence in situ hybridisation (FISH) to pachytene chromosomes we now provide direct physical evidence showing that Mi-1 is located at the border of the euchromatin and heterochromatin regions in the short arm (6S) and Aps-1 in the pericentromeric heterochromatin of the long arm (6L) close to the euchromatin. Taking into account both the estimated DNA content of hetero- and euchromatin regions and the compactness of the tomato chromosomes at pachytene (2 Mb/μm), our data suggest that Mi-1 and Aps-1 are at least 40 Mb apart, a base pair-to-centiMorgan relationship that is more than 50-fold higher than the average value of 750 kb/cM of the tomato genome. An integrated cytogenetic-molecular map of chromosome 6 is presented that provides a framework for physical mapping. Received: 24 July 1998 / Accepted: 14 August 1998     

Insights into chromosomal evolution of Cicadomorpha using fluorochrome staining and mapping 18S rRNA and H3 histone genes

The infraorder Cicadomorpha (Hemiptera) is a cosmopolitan species‐rich lineage of phytophagous insects. They have holocentric chromosomes and vary greatly in diploid number across families, with X0 as the predominant sex male mechanism. Here, we advance the understanding of chromosome mapping of repetitive elements of four families of cicadomorphan insects, the spittlebugs (Cercopidae), leafhoppers (Cicadellidae), and treehoppers (Aetalionidae and Membracidae). Sampled individuals from 19 species show considerable variation in diploid number, which may have originated from fusions between autosomes or between autosomes and the ancient X. The distribution of CMA₃⁺ blocks, primarily observed in low numbers in autosomal regions, was a conserved trait. Likewise, fluorescence in situ hybridization (FISH) mapping revealed mainly one locus per haploid genome for the 18S rRNA gene and for H3, each of which is located on distinct chromosomes. Despite the extensive variation in the number of autosomes and sex systems, the number of loci of ribosomal and H3 genes remained stable and may reflect the ancestral genome organizations in these groups. These results shed light on the chromosomal‐level organization in Cicadomorpha and provide new insights into the evolutionary history of karyotypes and repetitive elements in this diverse insect lineage.