Zhihua Zhou

Genetic structure and reproduction dynamics of Salix reinii during primary succession on Mount Fuji, as revealed by nuclear and chloroplast microsatellite analysis

The early stage of volcanic desert succession is underway on the southeastern slope of Mount Fuji. We used markers of nuclear microsatellites (simple sequence repeats; SSR) and chloroplast microsatellites (cpSSR) to investigate the population genetic structure and reproduction dynamics of Salix reinii, one of the dominant pioneer shrubs in this area. The number of S. reinii genets in a patch and the area of the largest genet within the patch increased with patch area, suggesting that both clonal growth and seedling recruitment are involved in the reproduction dynamics of S. reinii. Five polymorphic cpSSR markers were developed for S. reinii by sequencing the noncoding regions between universal sequences in the chloroplast genome. Nineteen different cpSSR haplotypes were identified, indicating that S. reinii pioneer genets were created by the long‐distance dispersal of seeds originating from different mother genets around the study site, where all vegetation was destroyed during the last eruption. Furthermore, the clustered distributions of different haplotypes within each patch or plot suggested that newly colonized genets tended to be generated from seeds dispersed near the initially established mother genets. These results revealed that the establishment of the S. reinii population on the southeastern slope of Mount Fuji involved two sequential modes of seed dispersal: long‐distance dispersal followed by short‐distance dispersal.

A Simple Method for Developing Microsatellite Markers using Amplified Fragments of Inter-simple Sequence Repeat (ISSR)

10 A primer IP1 designed from the sequenced region at one end of the microsatellite and for nested PCR another primer IP2 based on the sequence between IP1 and the microsatellite were prepared. These two primers were used to determine the other sequence flanking the microsatellite by a “walking” method. With this approach, we developed several microsatellite markers from Salix reinii, Pinus densiflora and Robinia pseudoacacia, respectively. The absence of enrichment processes and screening procedures makes it easier to develop microsatellite markers, and this approach provides an alternative for the development of microsatellite markers in any organism.

Spatial distribution of the subterranean mycelia and ectomycorrhizae of Suillus grevillei genets

Suillus grevillei, and found that one, SG-5, is species-specific to S. grevillei and polymorphic. Using the SG-5 marker, we analyzed for the first time the horizontal and vertical distribution of the subterranean parts of several S. grevillei genets. The spatial distribution of S. grevillei genets in the soil demonstrated that the development of S. grevillei sporocarps is correlated with that of extra-radical mycelia and ectomycorrhizae of the same genet, which are distributed in a narrow area. However, sporocarps are not always centered over the subterranean parts and the amount of subterranean mycelia and mycorrhizae is not always correlated to the number of sporocarps formed on them. No S. grevillei mycelia and mycorrhizae were detected beneath the positions where S. grevillei sporocarps emerged in the previous year. The observation indicates the rapid alteration of the subterranean parts of S. grevillei genets, and suggests that S. grevillei genets change location rather than merely extend their habitat year after year.

Patch establishment and development of a clonal plant, Polygonum cuspidatum, on Mount Fuji

Microsatellite analysis was used to investigate the patch establishment and development of Polygonum cuspidatum Sieb. et Zucc, a clonal herbaceous plant that dominates the primary succession on the southeast slope of Mount Fuji. Genotypes of P. cuspidatum in 155 patches at the study site differed from each other. This indicates that P. cuspidatum patches are initially established by seed dispersed on the bare scoria field, and not by clonal rhizome extension. Genetic differentiation was estimated using the FST values between subpopulations at the study site. There was almost no genetic differentiation between subpopulations, indicating the presence of massive gene flow. The pollen fathers of seeds and maternal genets of current‐year seedlings were inferred from the microsatellite allele composition by a simple exclusion method. The wide, random distribution of pollen fathers suggests that pollen dispersal occurs over a broad area. Maternal analysis showed a tendency for seed dispersal to be biased to the area nearby and down slope from the mother plants. Patch establishment under massive gene flow may result from such pollen and seed dispersal. To understand the process of patch development, aerial photographs taken from 1962 to 1999 were compared, and then genets in each of 36 patches were identified from the microsatellite genotypes of P. cuspidatum shoots. The comparison of aerial photographs showed that most of the patches enlarged each year and that some neighbouring patches combined during growth. Genet analysis demonstrated a high correlation between patch area and the area of the largest genet within it, and that new genets were recruited at the patch periphery. These findings indicate that both vegetative and sexual reproduction, i.e. rhizome extension and the establishment of new seedlings, contribute to the development of P. cuspidatum patches.

Genetic structure of pine sawyer Monochamus alternatus (Coleoptera: Cerambycidae) populations in Northeast Asia: consequences of the spread of pine wilt disease.

Abstract We studied the phylogeography and genetic diversity of the pine sawyer Monochamus alternatus (Hope) (Coleoptera: Cerambycidae) to understand its colonization dynamics, potential for further invasion, and potential species divergence. This species is the main vector of the pine wood nematode Bursaphelenchus xylophilus (Steiner and Buhrer), which is the causative agent of pine wilt disease in Japan. The genetic structure was studied using sequences of mitochondrial DNA and microsatellites. The phylogenetic analysis revealed two distinct lineages within M. alternatus. There is no clear boundary between haplotypic distributions of the two clades. Coalescence should have been extended by population subdivision. There might also be a fusion of the two distinct populations, and both are completely saturated. Analysis of the microsatellite genotypes of populations in Japan showed a complex genetic structure. Estimates of overall population differentiation (FST) were significantly different from zero. The populations are thought to be at demographical nonequilibrium or to show restricted gene flow among prefectures. Although neighboring populations often had similar genetic compositions, significant isolation by distance in the total population was not detected. It is suggested that population expansion may have occurred not only by natural dispersal on a small scale, but also by long-distance dispersal likely enhanced by the relocation, (by humans) of infested wood. Our data suggest that M. alternatus is a species capable of dispersing over a large area, and therefore, multiple invasions of M. alternatus from distant areas is a possibility.

Genet Distribution of Ectomycorrhizal Fungus Suillus grevillei Populations in Two Larix kaempferi Stands over Two Years

Suillus grevillei in two Larix kaempferi stands was determined over two years by inter-simple sequence repeat (ISSR) polymorphism analysis using primers, (GTG)5, (GCC)5 and (GACA)4. Thirty-five genets were identified from 67 sporocarps at the older stand (stand A in which the distribution of S. grevillei genet in 1997 was analyzed previously) in 1998, and 14 genets from 52 sporocarps at the younger stand (stand B) in 1997 and 1998. The characteristics of S. grevillei genets in stand A in 1998 were similar to those in 1997. A single genet was represented by 1.8 and 3.7 sporocarps on average in stands A and B, respectively. In stand A, 42 out of 61 genets, i.e., about 70% were represented by individual sporocarps compared to five out of 14 genets, i.e., about 35% in stand B. The largest and the average genet sizes was 6.8 m and less than 1 m in stand A, and 11 m and 2.3 m in stand B, respectively. A t-test showed the genet size in stand A to be significantly smaller than that in stand B. The above results indicate that the smaller genets of the S. grevillei population in stand A might be due to environmental conditions not genetic traits specific to this species. Observations over two years showed that although some genets formed sporocarps in both 1997 and 1998, many formed sporocarps only in one of the two years. Emerging positions of sporocarps in 1997 and 1998, which belonged to the same genet, were similar but not identical, about 2 m apart, suggesting mobility in the subterranean parts of ECM fungal genets.

Genetic Structure of Populations of the Pinewood Nematode Bursaphelenchus xylophilus, the Pathogen of Pine Wilt Disease, Between and Within Pine Forests

ABSTRACT We analyzed the genetic structure of Bursaphelenchus xylophilus populations within individual trees (subpopulations) in three distant pine forests (Tanashi, Tsukuba, and Chiba in Japan) based on the polymorphism of four microsatellite (SSR) markers. Most of the nematodes from subpopulations in Tanashi showed the same genotype over 2 years, indicating that nematodes of that genotype dominated there for years. In contrast, 16 and 15 genotypes were identified in nematode populations from Tsukuba and Chiba, respectively. Despite the high genetic diversity within the Tsukuba and Chiba populations, extremely low genetic diversity was observed within the subpopulations. The genetic difference between the Tsukuba and Chiba populations was significantly smaller than that between Tanashi and either Tsukuba or Chiba. Observed heterozygosity was significantly less than expected based on Hardy-Weinberg equilibrium. These findings are best explained by a founder effect, geographic isolation between populations, explosive nematode multiplication from a small number within individual trees, and the Wahlund effect.

Molecular phylogeny of ectomycorrhizal Pisolithus fungi associated with pine, dipterocarp, and eucalyptus trees in Thailand

The phylogenetic relationships among 135 Pisolithus basidiomes and two isolates collected from three pine forests, a pine-dipterocarp forest, two dipterocarp forests, and 29 eucalyptus plantations in Thailand were investigated. Internal transcribed spacer (ITS) polymorphism analyses, including terminal RFLP, divided them into 26 groups. The ITS in a representative basidiome of each group was sequenced, and a phylogenetic analysis was performed. The dendrogram suggested that at least three Pisolithus species are present in Thailand. Pisolithus basidiomes collected in the pine forests and under some Shorea roxburghii trees in a pine-dipterocarp forest corresponded to species 5 as previously described by Martin et al. in 2002. Those collected under S. roxburghii and Dipterocarp alatus trees in the dipterocarp forests did not match any previously reported species. Basidiomes collected from the eucalyptus plantations were all identified as Pisolithus albus.