Cryptaphelenchus abietis n. sp. (Tylenchomorpha: Aphelenchoididae) isolated from Cryphalus piceae (Ratzeburg) (Coleoptera: Scolytinae) emerged from Abies veitchii Lindl. (Pinaceae) from Nagano, Japan

Summary An undescribed Cryptaphelenchus species was isolated from a bark beetle, Cryphalus piceae that had emerged from a dead log of the Veitch’s fir, Abies veitchii, collected from Sugadaira Montane Research Center, University of Tsukuba, Nagano, Japan. The new species is characterised by its female post-vulval uterine sac (PUS) of less than one vulval body diam. in length and female posterior body end (tail) conical with elongate posterior part and variably shaped tip, seven male genital papillae, which are composed/arranged as a precloacal P1, P2 pair slightly anterior to cloacal opening, and two small pairs of glandpapillae near tail tip and very narrow bursal flap-like cuticular extension surrounding the male tail. In addition to these characters, the male apophysis appears wing-like in ventral view. In possessing an elongate posterior part, Cryptaphelenchus abietis n. sp. shares the female tail shape with C. borlossi, C. leptocaudus and C. sutoricus, and shares a short PUS with C. iranicus, C. varicaudatus, C. baujardi and C. paravaricaudatus. However, the new species can be distinguished from these species by other typological and morphometric characters and its molecular phylogenetic status. Phylogenetically, the new species is closest to Bursaphelenchus minutus, but can be clearly distinguished by morphological and molecular sequence characters.

Effects of leaf age, elevation and light conditions on photosynthesis and leaf traits in saplings of two evergreen conifers, Abies veitchii and A. mariesii

Aims Subalpine coniferous species are distributed over a wide range of elevations in which they must contend with stressful conditions, such as high elevations and extended periods of darkness. Two evergreen coniferous species, Abies veitchii and Abies mariesii, dominate at low and high elevations, respectively, in the subalpine zone, central Japan. The aim of this study is to examine the effects of leaf age, elevation and light conditions on photosynthetic rates through changes in morphological and physiological leaf traits in the two species. Methods We here examined effects of leaf age, elevation and light conditions on photosynthesis, and leaf traits in A. veitchii and A. mariesii. Saplings of the two conifers were sampled in the understory and canopy gaps at their lower (1600 m) and upper (2300 m) distribution limits. Important Findings The two species showed similar responses to leaf age and different responses to elevation and light conditions in photosynthesis and leaf traits. The maximum photosynthetic rate of A. veitchii is correlated negatively with leaf mass per area (LMA) and non-structural carbohydrate (NSC) concentration. LMA increased at high elevations in the two species, whereas NSC concentrations increased only in A. veitchii. Therefore, the maximum photosynthetic rate of A. veitchii decreased at high elevations. Furthermore, maximum photosynthetic rates correlate positively with nitrogen concentration in both species. In the understory, leaf nitrogen concentrations decreased and increased in A. veitchii and A. mariesii, respectively. LMA decreased and the chlorophyll-to-nitrogen ratio increased in understory conditions only for A. mariesii, suggesting it has a higher light-capture efficiency in dark conditions than does A. veitchii. This study concluded that A. mariesii has more shade-tolerant photosynthetic and leaf traits and its photosynthetic rate is less affected by elevation compared with A. veitchii, allowing A. mariesii to survive in the understory and to dominate at high elevations.

Repair of severe winter xylem embolism supports summer water transport and carbon gain in flagged crowns of the subalpine conifer Abies veitchii

Xylem embolism induced by winter drought is a serious dysfunction in evergreen conifers growing at wind-exposed sites in the mountains. Some coniferous species can recover from winter embolism. The aim of this study was to determine whether wind direction influences embolism formation and/or repair dynamics on short windward and long leeward branches of asymmetrical `flagged' crowns. We analyzed the effect of branch orientation on percentage loss of xylem conductive area (PLC), leaf functional traits and the xylem:leaf area ratio for subalpine, wind-exposed flagged-crown Abies veitchii trees in the northern Yatsugatake Mountains of central Japan. In late winter, the shoot water potential was below −2.5 MPa, and the PLC exceeded 80% in 2-year-old branches, independent of branch orientation within a flagged crown. Both of these parameters almost fully recovered by summer. At branch internodes 4 years of age and older, seasonal changes in PLC were not found in either windward or leeward branches, but the PLC was higher in less leafy windward branches. The leaf nitrogen content and water-use efficiency of mature leaves were comparable between windward branches and leafy leeward branches. The ratio of xylem conductive area to total leaf area was the same for windward and leeward branches. These results indicate that the repair of winter xylem embolism allows leaf physiological functions to be maintained under sufficient leaf water supply, even on winter-wind-exposed branches. This permits substantial photosynthetic carbon gain during the following growing season on both windward and leeward branches. Thus, xylem recovery from winter embolism is a key trait for the survival of harsh winters and to support productivity on the individual level in flagged-crown A. veitchii trees.