Identification of cryptic species within liverwort Conocephalum conicum based on the volatile components.

Cryptic speciation refers to cases where species are clearly genetically differentiated, but show little or no morphological differences. This study investigated whether volatile components can be used to distinguish the cryptic species within the Conocephalum conicum complex. Thirteen samples were included in this study representing four cryptic species (A, F, J, L) and the recently described Conocephalum salebrosum (formerly cryptic species S) detected in a worldwide collection. Results received from GC-MS analyses showed some differences between samples, indicating the existence of chemical polymorphism. It is evident from both statistical analyses (CA and PCA), that cryptic species L appears to be the most differentiated species, with the volatile components not significantly shared with the rest of the types. The most characteristic compound of this type is the sesquiterpene alcohol, conocephalenol. Distinction between other examined cryptic species were also indicated. However species F and J, as well as species A and C. salebrosum, share a great similarity in their volatile composition and are grouped together in both CA and PCA. Despite their similarities, we were able to find chemical markers which can describe each species. Cubebol is characteristic for C. salebrosum, while cryptic species A produces (E)-methylcinnamate. The presence of a large amount of the monoterpene hydrocarbon, sabinene, is characteristic for cryptic species J. In one of the analyzed specimens belonging to the cryptic species F, a large amount of cyclocolorenone was detected. Chemical differentiation was correlated with the geographical distribution of the analyzed samples.

Adaptive evolution of rbcL in Conocephalum (Hepaticae, bryophytes).

An excess of nonsynonymous substitutions over synonymous ones has been regarded as an important indicator of adaptive evolution or positive selection at the molecular level. We now report such a case for rbcL sequences among cryptic species in Conocephalum (Hepaticae, Bryophytes). This finding can be regarded as evidence of adaptive evolution in several cryptic species (especially in F and JN types) within the genus. Bryophytes are small land plants with simple morphology. We can therefore expect the existence of several biologically distinct units or cryptic species within each morphological species. In our previous study, we found three rbcL types in Asian Conocephalum japonicum (Thunb.) Grolle and also found evidence strongly suggesting that the three types are reproductively isolated cryptic species. Additionally, we examined rbcL sequence variation in six cryptic species of C. conicum (L.) Dumort. previously recognized by allozyme analyses. As a result, we were able to discriminate the six cryptic species based only on their rbcL sequences. We were able to show that rbcL sequence variation is also useful in finding cryptic species of C. conicum.

HIGH LEVELS OF GENETIC VARIABILITY IN THE HAPLOID MOSS PLAGIOMNIUM CILIARE.

Horizontal starch-gel electrophoresis was used to measure variability at 14 enzyme loci from 13 natural populations of the dioecious moss Plagiomnium ciliare. Overall levels of genetic polymorphism were unexpectedly high for a haploid organism. Using a 1% frequency criterion, 71% of the loci surveyed were polymorphic for the species as a whole. The number of alleles per polymorphic locus for the species as a whole was 2.82 ± 0.34 (mean ± standard error), and mean gene diversity per locus was 0.078 ± 0.035. While total gene diversity (HT = 0.178) was similar to that observed for highly outcrossed diploid plants such as pines, the variance within (HS = 0.098 ± 0.027) and among (DST = 0.080 ± 0.033) populations was more evenly distributed than that reported for populations of conifers. Genetic distances between populations ranged from 0.0002 to 0.2064, with mosses from the Piedmont region of the southeastern United States showing less differentiation among populations than did mosses from the Appalachian Mountains. Gene diversity was much reduced in populations from disturbed, secondary forests in the Piedmont (0.058 ± 0.018) relative to those from minimally disturbed, primary forests in the mountains (0.146 ± 0.048). Intensive sampling within populations revealed heterogeneity even within small (5 × 5 cm) clumps. The discovery of high levels of genetic variability in a plant with a dominant haploid life cycle challenges the traditional view of bryophytes as a genetically depauperate group. Multipleniche selection is proposed as a possible explanation for this anomaly, but the data are also consistent with the view that allozyme polymorphisms are selectively neutral.