Evolution of cranial shape in a continental‐scale evolutionary radiation of Australian lizards

A defining character of adaptive radiations is the evolution of a diversity of morphological forms that are associated with the use of different habitats, following the invasion of vacant niches. Island adaptive radiations have been thoroughly investigated but continental scale radiations are more poorly understood. Here, we use 52 species of Australian agamid lizards and their Asian relatives as a model group, and employ three‐dimensional geometric morphometrics to characterize cranial morphology and investigate whether variation in cranial shape reflects patterns expected from the ecological process of adaptive radiation. Phylogenetic affinity, evolutionary allometry, and ecological life habit all play major roles in the evolution of cranial shape in the sampled lizards. We find a significant association between cranial shapes and life habit. Our results are in line with the expectations of an adaptive radiation, and this is the first time detailed geometric morphometric analyses have been used to understand the selective forces that drove an adaptive radiation at a continental scale.     

Regional patterns of biodiversity in New Guinea plants

Regional patterns of biodiversity in seven recently-studied, speciose groups of New Guinea plants (comprising 200 species, or 1–2% of the flora) are analysed with maps showing numbers of species in 1^o grid cells. Patterns are correlated with the tectonic history of New Guinea. The New Guinea orogen involved rocks of the northern margin of the Australian craton as well as the terranes accreted to the margin, and the current axial range is geologically and biologically composite. The southern Nothofagus has a main massing on the Australian craton portion of the New Guinea mountains. In contrast, four typical genera of Malesian rainforest (Parsonsia, Archidendron, Aglaia, Amyema) have centres of biodiversity on the accreted terranes north of the craton. There are 32 distinct tectono-stratigraphic terranes (some composite) which have been accreted to the craton at different times through the Tertiary and these may have travelled hundreds or even thousands of kilometres before docking. Finally, the 'decaisninoid group' of Loranthaceae and the fern Grammitis have centres of diversity on both the craton and the accreted terranes.     

Convergence in community structure and dietary adaptation in Australian possums and gliders and Malagasy lemurs

Abstract The possums and gliders of Australia and the lemurs of Madagascar are ideally suited for investigation of radiation and convergence in arboreal mammal communities because of their long history of independent radiation in similar biophysical environments. Possum and glider communities at 22 sites in Australia and lemur communities at 18 sites in Madagascar were compared to evaluate patterns of community and species convergence in two shared habitats (evergreen and deciduous monsoon rainforests) and three derived habitats (Australian eucalypt forests and heaths, and Malagasy thorn scrubs). Arboreal mammals were classified into five dietary guilds for comparison of community structure and species adaptation. There is little evidence of convergence in trophic structure at the community level, but strong evidence of convergence in dietary adaptation at the species and niche level. Malagasy rainforest communities were characterized by a higher proportion of frugivore-folivores, and Australian rainforest and moist eucalypt communities by a higher proportion of folivores and folivore-frugivores. Possum and glider communities in temperate eucalypt forests and heaths supported a higher proportion of nectarivores and exudivores. Overall species richness was significantly higher in Madagascar. Four hypotheses are erected to account for these differences. The relative scarcity of frugivores in Australian evergreen rainforests is accounted for by the predominance of bird-dispersed fruits, and fruiting phenologies unsuitable for mammal exploitation and dispersal. Higher folivore diversity in Australian evergreen rainforests is associated with a more pronounced seasonal shortage of edible fruits and new leaf, which has increased dependence on mature leaf. Folivore species richness is greatest in Australian moist eucalypt forests where structural complexity, sustained by serai responses to wildfire, permits a high level of vertical segregation. Increased nectarivory and exudivory in Australian temperate eucalypt forests and heaths is associated with Mediterranean winter rainfall regimes, which permit year round exudate production, and not with the absence of nectar feeding bats as previously supposed. A lower overall species richness in Australian rainforests is attributed to a longer history of contraction and fragmentation by anthropogenic fires (monsoon rainforests) and Pleistocene climatic change (tropical evergreen rainforests). A high degree of convergence is apparent between genera occupying folivore and wood gouging niches, in terms of gastrointestinal morphology (e.g. Pseudocheirus-Lepilemur) and dental morphology (e.g. Dactylopsila-Daubentonia). Divergences are most apparent in adaptations associated with frugivory, including larger body size, diurnality, and bipedal suspension and leaping modes of locomotion (in Eulemur spp.). This study highlights the importance of founding effects, competition from other vertebrate taxa, coevolution between animals and their food plants, and differences in biophysical environments, as determinants of mammalian radiation and convergence.     

Incipient adaptive radiation of New Zealand and Australian Microseris (Asteraceae): an amplified fragment length polymorphism (AFLP) study

The disjunct allotetraploid lineage of the North American genus Microseris in New Zealand and Australia originated from one or a few diaspores after a single introduction via long‐distance dispersal. The plants have evolved into four morphologically distinct ecotypes: ‘fine‐pappus’, ‘coastal’, ‘murnong’, and ‘alpine’, from which the first two are grouped as Microseris scapigera, mainly from New Zealand and Tasmania, and the latter two as M. lanceolata, endemic to the Australian mainland. Three chloroplast (cp) DNA types were distinguished in each of the species, but their distribution, especially in M. lanceolata, showed discrepancies with ecotype differentiation. Here, we analyse the genetic structure of the nuclear (n) DNA among two plants of each of 55 New Zealand, Tasmanian, and Australian Microseris populations for amplified fragment length polymorphisms (AFLPs). The nuclear genetic structure is compared to geographical, ecotype, and cpDNA distribution, in order to resolve and illustrate the early process of adaptive radiation. The strongest signal in the AFLP pattern was related to geographical separation, especially between New Zealand and Australian accessions, and suggested an initial range expansion after establishment. The ecotypic differentiation was less‐well reflected in the AFLP pattern, and evidence was found for the occurrence of hybridization among plants at the same geographical region, or after dispersal, irrespective of the cpDNA‐ and ecotypes. This indicated that the ecotype characteristics were maintained or re‐established by selection. It also showed that genetic differentiation is not an irreversible and progressive process in the early stage of adaptive radiation. Our results illustrate the precarious balance between geographical isolation and selection as factors that favour differentiation, and hybridization as factor that reduces differentiation.     

Effects of an adaptive zone shift on morphological and ecological diversification in terapontid fishes

A fundamental goal of evolutionary ecology is understanding the processes responsible for contemporary patterns of morphological diversity and species richness. Transitions across the marine–freshwater interface are regarded as key triggers for adaptive radiation of many clades. Using the Australian terapontid fish family as a model system we employed phylogenetic analyses to compare the rates of ecological (dietary) and morphological evolution between marine and freshwater species of the family. Results suggested significantly higher rates of phenotypic evolution in key dietary and morphological characters in freshwater species compared to marine counterparts. Moreover, there was significant correlation between several of these dietary and morphological characters, suggesting an underlying ecomorphological aspect to these greater rates of phenotypic evolution in freshwater clades. Australia’s biogeographic history, which has precluded colonisation by many of the major ostariophysan fish families that make up much global freshwater fish diversity, appears to have provided the requisite ‘ecological opportunity’ to facilitate the radiation of invading marine-derived fish clades.     

Senescence and hyperspectral reflectance of cotton leaves exposed to ultraviolet-B radiation and carbon dioxide

The objectives of this study were to determine the effects of UV-B radiation and atmospheric carbon dioxide concentrations ([CO(2)]) on leaf senescence of cotton by measuring leaf photosynthesis and chlorophyll content and to identify changes in leaf hyperspectral reflectance occurring due to senescence and UV-B radiation. Plants were grown in controlled-environment growth chambers at two [CO(2)] (360 and 720 micro mol mol(-1)) and three levels of UV-B radiation (0, 7.7 and 15.1 kJ m(-2) day(-1)). Photosynthesis, chlorophyll, carotenoids and phenolic compounds along with leaf hyperspectral reflectance were measured on three leaves aged 12, 21 and 30 days in each of the treatments. No interaction was detected between [CO(2)] and UV-B for any of the measured parameters. Significant interactions were observed between UV-B and leaf age for photosynthesis and stomatal conductance. Elevated [CO(2)] enhanced leaf photosynthesis by 32%. On exposure to 0, 7.7 and 15.1 kJ of UV-B, the photosynthetic rates of 30-day-old leaves compared with 12-day-old leaves were reduced by 52, 76 and 86%, respectively. Chlorophyll pigments were not affected by leaf age at UV-B radiation of 0 and 7.7 kJ, but UV-B of 15.1 kJ reduced the chlorophylls by 20, 60 and 80% in 12, 21 and 30-day-old leaves, respectively. The hyperspectral reflectance between 726 and 1142 nm showed interaction for UV-B radiation and leaf age. In cotton, leaf photosynthesis can be used as an indicator of leaf senescence, as it is more sensitive than photosynthetic pigments on exposure to UV-B radiation. This study revealed that, cotton leaves senesced early on exposure to UV-B radiation as indicated by leaf photosynthesis, and leaf hyperspectral reflectance can be used to detect changes caused by UV-B and leaf ageing.     

Functional and evolutionary correlations of steep leaf angles in the mexical shrubland

In the evergreen shrubland vegetation of Mexico (mexical), most of the species are sclerophyllous woody plants with steep leaf angles. This architectural pattern has been interpreted as a strategy to cope with water shortages and high radiation. However, the current association between evergreenness and steep leaf angles across mexical plant species could be the result of an adaptive association achieved through correlated evolutionary change between both traits or, alternatively, may be the result of common evolutionary ancestry. In this study, we quantified leaf angle in 28 dominant species under a phylogenetic framework and evaluated the functional implications of the observed range of leaf angles in terms of leaf temperature, water potentials and transpiration by combining manipulative experiments restraining leaves horizontally with microclimatic and stomatal conductance measurements in selected species and energy balance calculations. Horizontally restrained leaves exhibited reduced water potentials and stomatal conductances, and significantly increased temperatures and transpiration rates. Steeply inclined leaves operated near air temperatures and could sustain relatively high stomatal conductances during the dry season since they were associated with low transpiration rates. Phylogenetic analyses showed that steep leaf angles evolved in a correlated fashion in evergreen species. The functional consequences of leaf angle together with the phylogenetic analysis indicate the adaptive nature of this trait which allows the evergreen species to cope with arid conditions and therefore to persist within the mexical community.     

Stomatal types of the genus Acacia (Fabaceae, Mimosoideae): an appraisal of diversity and taxonomic interest

The stomatal types of 102 species illustrating the different subdivisions of Bentham's classification of the genus Acacia were studied at two or three ontogenetic stages: first pinnate leaf to bipinnate leaves or to phyllode. Six stomatal types are recognized on the basis of Guyot's nomenclature (1966): 1, 2, 3, 4, 4', 6; a new type (3') is described. The specialization of the leaf up to the phyllode stage is followed by a decrease of diversity of the stomatal formula and an increasing frequency of the 'basic core' 3, 3', 4. The distinction between the two Australian groups of bipinnate species (series Pulchellae and Botrycephalae) is confirmed. Possible relationships between the cosmopolitan series Vulgares (the most primitive group) and some Australian taxa as well as between the Pulchellae and some phyllodic species from the Australian series Phyllodineae are commented on. The series Gummiferae looks quite distinct from other groups.     

Response of sugar beet plants to ultraviolet-B (280–320 nm) radiation and Cercospom leaf spot disease

Sugar beet ( Beta vulgaris L.) plants injected with Cercospora beticota Sace. as well as non-infected plants were grown under visible light with or without ultraviolet-B (UV-B, 280–320 nm) radiation for 40 days. An interaction between UV-B radiation and Cercospora leaf spot disease was observed, resulting in a large reduction in leaf chlorophyll content, dry weight of leaf laminae, petioles and storage roots. Lipid peraxidation in leaves also increased the most under the combined treatments. This was also true for ultraweak luminescence from both adaxial and abaxial leaf surfaces. However, no correlation between lipid peroxidation and ultraweak luminescence was observed. Ultraviolet-B radiation given alone appeared to have either a stimulating effect, giving an increase in dry weight of laminae and reducing lipid peroxidation, or no effect. This lack of effect was seen in the absence of change in dry weight of storage roots and chlorophyll content relative to controls. The :study demonstrated a harmful interaction between UV-B radiation and Cercospom leaf spot disease on sugar beet.     

Signatures of diversifying selection at EST‐SSR loci and association with climate in natural Eucalyptus populations

Understanding the environmental parameters that drive adaptation among populations is important in predicting how species may respond to global climatic changes and how gene pools might be managed to conserve adaptive genetic diversity. Here, we used Bayesian F_ST outlier tests and allele–climate association analyses to reveal two Eucalyptus EST‐SSR loci as strong candidates for diversifying selection in natural populations of a southwestern Australian forest tree, Eucalyptus gomphocephala (Myrtaceae). The Eucalyptus homolog of a CONSTANS‐like gene was an F_ST outlier, and allelic variation showed significant latitudinal clinal associations with annual and winter solar radiation, potential evaporation, summer precipitation and aridity. A second F_ST outlier locus, homologous to quinone oxidoreductase, was significantly associated with measures of temperature range, high summer temperature and summer solar radiation, with important implications for predicting the effect of temperature on natural populations in the context of climate change. We complemented these data with investigations into neutral population genetic structure and diversity throughout the species range. This study provides an investigation into selection signatures at gene‐homologous EST‐SSRs in natural Eucalyptus populations, and contributes to our understanding of the relationship between climate and adaptive genetic variation, informing the conservation of both putatively neutral and adaptive components of genetic diversity.     

Convergence and non-convergence of plant traits in climatically and edaphically matched sites in Mediterranean Australia and South Africa

Abstract This paper compares the occurrence of plant traits in five edaphically matched sites at the Barrens, southwestern Australia and the Agulhas Plain, southwestern South Africa. The two regions are very closely matched in terms of their Mediterranean-type climates, landforms, soil types and disturbance regimes. On both continents, matched sites on all substrata (siliceous sand, quartzite, laterite, limestone and calcareous sand) support sclerophyllous shrublands with a similar mix of growth forms. Soils from all substrata in both Australia and South Africa are extremely nutrient-poor except for the calcareous sands where high levels of phosphorus were recorded. Contrary to expectations, Australian soils are not generally less fertile than their South African counterparts. The frequency of species in different leaf consistence categories was similar on the two continents, as was the leaf specific mass of overstorey shrubs from all substrata. Woody plants with leaf spines are significantly more frequent on Australian nutrient-poor substrata. Among woody plants, species with canopy-stored seed are significantly more frequent on Australian nutrient-poor sites, whereas species with bird-dispersed fruits and inter-fire germination are significantly more frequent on South African limestone and calcareous sand. There was good evidence for convergence between the two continents in the frequency of other seed biological traits. The study indicates strong convergence between Australian and South African shrublands in the frequency of a wide range of traits relating to plant form and function. Examples of non-convergence are probably due to regional and historical processes rather than differences in the contemporary physical environments of the two study areas.     

The phenomenon of adaptive response in radiobiology]

Consideration is given to various adaptive reactions to low-level radiation, their association with an absorbed dose, dose rate, radiation quality and time-interval between exposures, as well as with a cell cycle phase. Possible mechanisms of the adaptive response and the character and role of DNA damages, that can induce gene expression of the adaptive response, are discussed. The data on the influence of a preliminary long-term exposure to low-level radiation on the radiosensitivity of biological objects are analyzed with due regard for the adaptive cell response. It is concluded that the adaptive response of cells to ionizing radiation is a particular case of the phenomenon of cell adaptation to the effect of genotoxic factors of the environment.     

Adaptive Radiation in Mediterranean Cistus (Cistaceae)

Background

Adaptive radiation in Mediterranean plants is poorly understood. The white-flowered Cistus lineage consists of 12 species primarily distributed in Mediterranean habitats and is herein subject to analysis.

Methodology/Principal Findings

We conducted a “total evidence” analysis combining nuclear (ncpGS, ITS) and plastid (trnL-trnF, trnK-matK, trnS-trnG, rbcL) DNA sequences and using MP and BI to test the hypothesis of radiation as suggested by previous phylogenetic results. One of the five well-supported lineages of the Cistus-Halimium complex, the white-flowered Cistus lineage, comprises the higher number of species (12) and is monophyletic. Molecular dating estimates a Mid Pleistocene (1.04±0.25 Ma) diversification of the white-flowered lineage into two groups (C. clusii and C. salviifolius lineages), which display asymmetric characteristics: number of species (2 vs. 10), leaf morphologies (linear vs. linear to ovate), floral characteristics (small, three-sepalled vs. small to large, three- or five-sepalled flowers) and ecological attributes (low-land vs. low-land to mountain environments). A positive phenotype-environment correlation has been detected by historical reconstructions of morphological traits (leaf shape, leaf labdanum content and leaf pubescence). Ecological evidence indicates that modifications of leaf shape and size, coupled with differences in labdanum secretion and pubescence density, appear to be related to success of new species in different Mediterranean habitats.

Conclusions/Significance

The observation that radiation in the Cistus salviifolius lineage has been accompanied by the emergence of divergent leaf traits (such as shape, pubescence and labdanum secretion) in different environments suggets that radiation in the group has been adaptive. Here we argued that the diverse ecological conditions of Mediterranean habitats played a key role in directing the evolution of alternative leaf strategies in this plant group. Key innovation of morphological characteristics is supported by our dated phylogeny, in which a Mediterranean climate establishment (2.8 Ma) predated the adaptive radiation of the white-flowered Cistus.     

Seasonal fluctuations in the concentration of UV-absorbing compounds in the leaves of some Mediterranean plants under field conditions

Leaves of 14 representative Mediterranean plant species were collected on a monthly basis and assayed for UV-absorbing compounds concentration, either on an area or a dry mass basis, from 1995 to 1997. Strong seasonal fluctuations were observed in eight species (all evergreens, two phrygana, one deciduous, one summer perennial and one winter perennial). Two different patterns of changing concentrations of UV-absorbing compounds were observed. In the first, concentration of these compounds was higher in young developing leaves and concentration declined during maturation, whereas in other plants, the opposite trend was observed. These differences could be attributed to the particular leaf surface morphology of each plant. The observed seasonal fluctuations of UV-absorbing compounds seem to be more correlated to developmental processes, than to seasonal fluctuations of the naturally occurring UV-B radiation. Most of the winter perennials did not show strong fluctuations during the period of development. The concentration of these compounds varied not only on a seasonal basis among the examined plants, but between different life forms as well: during winter, examination of the leaves of 13 species showed that evergreen sclerophylls and phrygana had at least two-fold higher concentration of UV-B-absorbing compounds on a leaf area basis than winter perennials. In addition, during the same season and irrespective of life form and species, the absorbance at 300 nm per unit of mature leaf area followed an asymptotic exponential decrease when specific leaf area increased. The UV-B radiation screening capacity of the leaves of these plants is discussed in relation to each adaptive strategy.     

Susceptibility to UV damage in Impatiens capensis (Balsaminaceae): testing for opportunity costs to shade-avoidance and population differentiation

Plastic increases in leaf secondary compounds may be an adaptive strategy that reduces the damaging effects of high-energy, ultraviolet radiation (UV). Here, we examine (1) the relationship between fitness and anthocyanin and flavonoid concentrations in experimental, UV environments, (2) the effects of UV on Impatiens capensis plants derived from woodland and clearing sites, and (3) whether susceptibility to UV damage is reduced by exposure to high ratios of red?:?far-red wavelengths (R?:?FR), which also stimulate the production of leaf compounds. Seedlings from each site were exposed to either high R?:?FR typical of sunlight or low R?:?FR characteristic of foliar shade, after which plants were moved into ambient UV or UV-removal treatments. Ultraviolet radiation stimulated the production of anthocyanins and flavonoids. However, higher anthocyanin concentrations were associated with lower biomass in the UV environment. Relative to the clearing population, reproductive output of the woodland population was more detrimentally affected by exposure to UV, despite its higher concentration of anthocyanins. Increased anthocyanin production may therefore be a stress response rather than an adaptive one. The greater tolerance of the clearing population to UV suggests that populations with an evolutionary history of UV exposure evolve mechanisms to limit damage. The R?:?FR pretreatments did not influence susceptibility to UV damage.     

Acumen function in leaves and its vertical distribution in a tropical rain forest of Costa Rica

Water retention on the leaf surface can be maladaptive to the plant because it increases the colonization of epiphylls and interferes with the physiologic processes of the leaf, diminishing the photosynthetic capacity. To test if leaf driptips facilitate leaf drying after rainfall in a tropical rain forest of Costa Rica, we (1) experimentally measured the capacity to retain water on leaf surfaces of 30 plant species before and after driptip removal, and (2) analyzed the development of driptips along forest strata. We expected leaf driptips to be less developed in the upper strata due to the environmental conditions of the canopy (i.e., high solar radiation, strong winds and low relative humidity), which favor the natural drying of leaves. The presence of driptips increased 100% the water run off capacity of leaves in all the analyzed species. Also, the development of leaf driptips was smaller in canopy species than in understory species. Additionally, they became less developed in canopy species as trees increased in height. These results support the hypothesis that the adaptive role of driptips is to facilitate the drying of leaf surfaces.     

Links between leaf anatomy and leaf mass per area of herbaceous species across slope aspects in an eastern Tibetan subalpine meadow

Leaf anatomy varies with abiotic factors and is an important trait for understanding plant adaptive responses to environmental conditions. Leaf mass per area (LMA) is a key morphological trait and is related to leaf performance, such as light‐saturated photosynthetic rate per leaf mass, leaf mechanical strength, and leaf lifespan. LMA is the multiplicative product of leaf thickness (LT) and leaf density (LD), both of which vary with leaf anatomy. Nevertheless, how LMA, LT, and LD covary with leaf anatomy is largely unexplored along natural environmental gradients. Slope aspect is a topographic factor that underlies variations in solar irradiation, air temperature, humidity, and soil fertility. In the present study, we examined (1) how leaf anatomy varies with different slope aspects and (2) how leaf anatomy is related to LMA, LD, and LT. Leaf anatomy was measured for 30 herbaceous species across three slope aspects (south‐, west‐, and north‐facing slopes; hereafter, SFS, WFS, and NFS, respectively) in an eastern Tibetan subalpine meadow. For 18 of the 30 species, LMA data were available from previous studies. LD was calculated as LMA divided by LT. Among the slope aspects, the dominant species on the SFS exhibited the highest LTs with the thickest spongy mesophyll layers. The thicker spongy mesophyll layer was related to a lower LD via larger intercellular airspaces. In contrast, LD was the highest on NFS among the slope aspects. LMA was not significantly different among the slope aspects because higher LTs on SFS were effectively offset by lower LDs. These results suggest that the relationships between leaf anatomy and LMA were different among the slope aspects. Mechanisms underlying the variations in leaf anatomy may include different solar radiation, air temperatures, soil water, and nutrient availabilities among the slope aspects.     

Two different strategies of Mediterranean macchia plants to avoid photoinhibitory damage by excessive radiation levels during summer drought

The adaptive strategies to high radiation and water stress of the drought tolerant evergreen sclerophylls Quercus coccifera and Arbutus unedo are compared to those of the semi-deciduous Cistus spp. (C. albidus and C. monspeliensis). Cistus spp. partially avoided drought by a marked reduction of their transpirational surface through leaf abscission during summer, when predawn water potential declined below -5.5 MPa. Chlorophyll fluorescence measurements revealed a reversible diurnal decrease of maximum photochemical efficiency of PSII (F_v/F_m), which became more accentuated during summer drought in all species. An important strategy to avoid damage by excessive radiation levels in Cistus spp. was the structural regulation of light interception through leaf angle changes, from a more horizontal orientation in spring (< 35°) to a more vertical orientation in summer (> 70°). Horizontal orientated leaves were highly susceptible to photoinhibition, and excessive radiation often resulted in irreversible photodamage followed by leaf abscission during summer, whereas vertical leaf orientation appeared to protect the leaf from severe photoinhibition. Still, these mechanisms were not fully successful in avoiding chronic photoinhibition, and predawn F_v/F_m values remained low in Cistus spp. during summer (only exhibiting a partial overnight recovery). Evergreen sclerophylls were less susceptible to photoinhibition, and the diurnal decline in F_v/F_m remained fully reversible during drought. Structural regulation of light interception was not found to be an important strategy in these species, and only small, though significant changes in leaf angle occurred. The ecological importance of the adaptive strategies of each functional group is discussed.     

Oviposition site selection by a lepidopteran leafminer in response to heterogeneity of leaf surface conditions: structural traits and microclimates

1. Leafminer larvae are sedentary and make feeding tracks called mines. Their spatial distribution in trees affects their growth and survival through interaction with the heterogeneity of environments, such as leaf traits and microclimate. Lepidopteran leafminers that mine lower leaf surfaces have shown evolutionary radiation, suggesting that lower surfaces improve leafminer performance. 2. The lepidopteran multivoltine leafminer Phyllocnistis sp. Zeller (Gracirallidae: Phyllocnistinae) uses the Japanese privet Ligustrum japonicum Thunb. (Oleaceae). It mines only the lower‐surface epidermal layer of primary shoot leaves early in the occurrence season, but once lammas shoots appear, which happens in seasons other than spring, it preferentially uses the lower surface, but also uses the upper surface of the leaves. This study examined whether selection of oviposition sites was associated with the structural traits and microclimate of the leaf surface. 3. The shift of oviposition site from primary to lammas shoot leaves followed increasing hardness and epidermal cell wall thickness of primary shoot leaves during leaf development, and mine initiation rates decreased below 20% after oviposition on mature primary shoot leaves. Preference for the lower surface was related to the thinner cuticle. However, the thinner cuticle of the upper surface on lammas shoot leaves allowed Phyllocnistis sp. to expand its mining sites to both surfaces with no decrease in mine initiation and emergence rates. 4. Microclimates (leaf surface and mine temperatures) did not differ between upper and lower surfaces, suggesting that microclimate did not affect oviposition site selection by Phyllocnistis sp. These results suggest that the adaptive radiation of lower‐surface mining may have been influenced by the leaf surface characteristics.