Katsushi Kuroda

Detection in situ and characterization of lignin in the G-layer of tension wood fibres of Populus deltoides

The occurrence of lignin in the additional gelatinous (G-) layer that differentiates in the secondary wall of hardwoods during tension wood formation has long been debated. In the present work, the ultrastructural distribution of lignin in the cell walls of normal and tension wood fibres from poplar (Populus deltoides Bartr. ex Marshall) was investigated by transmission electron microscopy using cryo-fixation–freeze-substitution in association with immunogold probes directed against typical structural motifs of lignin. The specificity of the immunological probes for condensed and non-condensed guaiacyl and syringyl interunit linkages of lignin, and their high sensitivity, allowed detection of lignin epitopes of definite chemical structures in the G-layer of tension wood fibres. Semi-quantitative distribution of the corresponding epitopes revealed the abundance of syringyl units in the G-layer. Predominating non-condensed lignin sub-structures appeared to be embedded in the crystalline cellulose matrix prevailing in the G-layer. The endwise mode of polymerization that is known to lead to these types of lignin structures appears consistent with such an organized cellulose environment. Immunochemical labelling provides the first visualization in planta of lignin structures within the G-layer of tension wood. The patterns of distribution of syringyl epitopes indicate that syringyl lignin is deposited more intensely in the later phase of fibre secondary wall assembly. The data also illustrate that syringyl lignin synthesis in tension wood fibres is under specific spatial and temporal regulation targeted differentially throughout cell wall layers.

Cryo-scanning electron microscopic study on freezing behavior of xylem ray parenchyma cells in hardwood species

Differential thermal analysis (DTA) has indicated that xylem ray parenchyma cells (XRPCs) of hardwood species adapt to freezing of apoplastic water either by deep supercooling or by extracellular freezing, depending upon the species. DTA studies indicated that moderately cold hardy hardwood species exhibiting deep supercooling in the XRPCs were limited in latitudinal distribution within the -40 degrees C isotherm, while very hardy hardwood species exhibiting extracellular freezing could distribute in colder areas beyond the -40 degrees C isotherm. Predictions based on the results of DTA, however, indicate that XRPCs exhibiting extracellular freezing may appear not only in very hardy woody species native to cold areas beyond the -40 degrees C isotherm but also in less hardy hardwood species native to tropical and subtropical zones as well as in a small number of moderately hardy hardwood species native to warm temperate zones. Cryo-scanning electron microscopic (cryo-SEM) studies on the freezing behavior of XRPCs have revealed some errors in DTA. These errors are originated mainly due to the overlap between exotherms produced by freezing of water in apoplastic spaces (high temperature exotherms, HTEs) and exotherms produced by freezing of intracellular water of XRPCs by breakdown of deep supercooling (low temperature exotherms, LTEs), as well as to the shortage of LTEs produced by intracellular freezing of XRPCs. In addition, DTA results are significantly affected by cooling rates employed. Further, cryo-SEM observations, which revealed the true freezing behavior of XRPCs, changed the previous knowledge of freezing behavior of XRPCs that had been obtained by freeze-substitution and transmission electron microscopic studies. Cryo-SEM results, in association with results obtained from DTA that were reconfirmed or changed by observation using a cryo-SEM, revealed a clear tendency of the freezing behavior of XRPCs in hardwood species to change with changes in the temperature in the growing conditions, including both latitudinal and seasonal temperature changes. In latitudinal temperature changes, XRPCs in less hardy hardwood species native to tropical and subtropical zones exhibited deep supercooling to -10 degrees C, XRPCs in moderately hardy hardwood species native to temperate zones exhibited a gradual increase in the supercooling ability to -40 degrees C from warm toward cool temperate zones, and XRPCs in very hardy hardwood species native to boreal forests exhibited extracellular freezing via an intermediate form of freezing behavior between deep supercooling and extracellular freezing. In seasonal temperature changes, XRPCs in hardwood species native to temperate zones changed their supercooling ability from a relatively low degree in summer to a high degree in winter. XRPCs in hardwood species native to boreal forests changed their freezing behavior from deep supercooling to -10 degrees C in summer to extracellular freezing in winter. These results indicate that the freezing behavior of XRPCs in hardwood species tends to shift gradually from supercooling of -10 degrees C, to a gradual increase in the deep supercooling ability to -40 degrees C or less, and finally to extracellular freezing as a result of cold acclimation in response to both latitudinal and seasonal temperature changes. It is thought that these temperature-dependent changes in the freezing behavior of XRPCs in hardwood species are mainly controlled by changes in cell wall properties, although no distinct changes were detected by electron microscopic observations in cell wall organization between hardwood species or between seasons. Evidence of temperature-dependent changes in the freezing behavior of XRPCs in hardwood species provided by the results of studies using a cryo-SEM has indicated the need for further investigation to clarify cold acclimation-induced cell wall changes at the sub-electron microscopic level in order to understand the mechanisms of freezing adaptation.

Xylem Ray Parenchyma Cells in Boreal Hardwood Species Respond to Subfreezing Temperatures by Deep Supercooling That Is Accompanied by Incomplete Desiccation

It has been accepted that xylem ray parenchyma cells (XRPCs) in hardwood species respond to subfreezing temperatures either by deep supercooling or by extracellular freezing. Present study by cryo-scanning electron microscopy examined the freezing responses of XRPCs in five boreal hardwoods: Salix sachalinensis Fr. Schmit, Populus sieboldii Miq., Betula platyphylla Sukat. var japonica Hara,Betula pubescens Ehrh., and red osier dogwood (Cornus sericea), in which XRPCs have been reported to respond by extracellular freezing. Cryo-scanning electron microscopy observations revealed that slow cooling of xylem to −80°C resulted in intracellular freezing in the majority of XRPCs in S. sachalinensis, an indication that these XRPCs had been deep supercooled. In contrast, in the majority of XRPCs in P. sieboldii, B. platyphylla, B. pubescens, and red osier dogwood, slow cooling to −80°C produced slight cytorrhysis without clear evidence of intracellular freezing, suggesting that these XRPCs might respond by extracellular freezing. In these XRPCs exhibited putative extracellular freezing; however, deep etching revealed the apparent formation of intracellular ice crystals in restricted local areas. To confirm the occurrence of intracellular freezing, we rewarmed these XRPCs after cooling and observed very large intracellular ice crystals as a result of the recrystallization. Thus, the XRPCs in all the boreal hardwoods that we examined responded by deep supercooling that was accompanied with incomplete desiccation. From these results, it seems possible that limitations to the deep-supercooling ability of XRPCs might be a limiting factor for adaptation of hardwoods to cold climates.

Determination of the Role of Cold Acclimation-Induced Diverse Changes in Plant Cells from the Viewpoint of Avoidance of Freezing Injury

Cold acclimation is a complex adaptive mechanism by which plants survive freezing in winter. During cold acclimation, diverse intracellular and extracellular changes occur. Although most of these changes are related to the acquirement of freezing tolerance, the exact role of these changes in the attainment of freezing tolerance is still unclear. In this review, we suggest the possible role of some of these cold acclimation-induced changes in relation with increased freezing tolerance from the viewpoint of inhibition of freezing injury produced by close approach of membranes.

Ultrastructural study of deep supercooling of xylem ray parenchyma cells from Styrax obassia

Abstract Some of the water in the xylem of a woody species ( Styrax obassia Sieb. et Zucc.), collected during the summer, appeared to exhibit deep supercooling and the breakdown of supercooling at around - 20°C, as determined by differential thermal analysis (DTA). Ultrastructural observations of the low-temperature behaviour of the xylem, using both cryo-scanning electron microscopy (cryo-SEM) and freeze-fracture replica techniques, provided direct evidence that xylem ray parenchyma cells can be deeply supercooled to around - 20°C and that the breakdown of supercooling produces intracellular freezing in the ray parenchyma cells. Ultrastructural observations also confirmed that the supercooling of ray parenchyma cells was basically unaffected by the presence or absence of bulk water in the neighbouring tracheary elements, and that individual ray parenchyma cells acted as isolated droplets of water. Furthermore, the present ultrastructural study provides clear evidence that intracellular freezing upon the breakdown of deep supercooling results in severe damage to plasma membranes. Nontheless, the characteristics of supercooling reappeared in the ray parenchyma cells upon recooling.

Supercooling of xylem ray parenchyma cells in tropical and subtropical hardwood species

Abstract The freezing behavior of xylem ray parenchyma cells in several woody species, Ficus elastica, F. microcarpa, Mangifera indica, Hibiscus Rosa-sinensis, and Schefflera arboricola, that are native to non-frost tropical and subtropical zones, was investigated by differential thermal analysis (DTA), cryo-scanning electron microscopy (cryo-SEM) and freeze-replica electron microscopy. Although profiles after DTA did not exhibit clear evidence of supercooling in the xylem ray parenchyma cells, electron microscopy revealed that the majority of xylem ray parenchyma cells in all of the woody species examined were supercooled to around –10°C upon freezing temperatures and were not frozen extracellularly. It seems likely that DTA failed to reveal the low temperature exotherm (LTE), that is produced by breakdown of supercooling in the xylem ray parenchyma cells as a consequence of the overlap between the high temperature exotherm and the LTE in each case. The xylem ray parenchyma cells in these woody species were very sensitive to dehydration, and supercooling had, to some extent, a protective effect against freezing injury. It is suggested that the capacity for supercooling of xylem ray parenchyma cells of tropical and subtropical woody species might be the result of inherent structural characteristics, such as rigid cell walls and compact xylem tissues, rather than the result of positive adaptation to freezing temperatures. The present and previous results together indicate that the responses of xylem ray parenchyma cells in a wide variety of hardwood species to freezing temperatures can be explained as a continuum, the specifics of which depend upon the temperatures of the growing conditions.

Seasonal variation in formation, structure, and chemical properties of phloem in Picea abies as studied by novel microtechniques

AbstractMain conclusionPhloem production and structural development were interlinked with seasonal variation in the primary and secondary metabolites of phloem. Novel microtechniques provided new perspectives on understanding phloem structure and chemistry. To gain new insights into phloem formation in Norway spruce (Picea abies), we monitored phloem cell production and seasonal variation in the primary and secondary metabolites of inner bark (non-structural carbohydrates and phenolic stilbene glucosides) during the 2012 growing season in southern and northern Finland. The structure of developing phloem was visualised in 3D by synchrotron X-ray microtomography. The chemical features of developing phloem tissues isolated by laser microdissection were analysed by chemical microanalysis. Within-year phloem formation was associated with seasonal changes in non-structural carbohydrates and phenolic extractive contents of inner bark. The onset of phloem cell production occurred in early and mid-May in southern and northern Finland, respectively. The maximal rate of phloem production and formation of a tangential band of axial phloem parenchyma occurred in mid-June, when total non-structural carbohydrates peaked (due to the high amount of starch). In contrast, soluble sugar content dropped during the most active growth period and increased in late summer and winter. The 3D visualisation showed that the new axial parenchyma clearly enlarged from June to August. Sub-cellular changes appeared to be associated with accumulation of stilbene glucosides and soluble sugars in the newest phloem. Stilbene glucosides also increased in inner bark during late summer and winter. Our findings may indicate that stilbene biosynthesis in older phloem predominantly occurs after the formation of the new band(s) of axial parenchyma. The complementary use of novel microtechniques provides new perspectives on the formation, structure, and chemistry of phloem.

Freezing behavior of xylem ray parenchyma cells in softwood species with differences in the organization of cell walls

SummaryBy cryo-scanning electron microscopy we examined the effects of the organization of the cell walls of xylem ray parenchyma cells on freezing behavior, namely, the capacity for supercooling and extracellular freezing, in various softwood species. Distinct differences in organization of the cell wall were associated with differences in freezing behavior. Xylem ray parenchyma cells with thin, unlignified primary walls in the entire region (all cells inSciadopitys verticillata and immature cells inPinus densiflora) or in most of the region (mature cells inP. densiflora and all cells inP. pariflora var.pentaphylla) responded to freezing conditions by extracellular freezing, whereas xylem ray parenchyma cells with thick, lignified primary walls (all cells inCrytomeria japonica) or secondary walls (all cells inLarix leptolepis) in most regions responded to freezing by supercooling. The freezing behavior of xylem ray parenchyma cells inL. leptolepis changed seasonally from supercooling in summer to extracellular freezing in winter, even though no detectable changes in the organization of cell walls were apparent. These results in the examined softwood species indicate that freezing behavior of xylem ray parenchyma cells changes in parallel not only with clear differences in the organization of cell walls but also with subtle sub-electron-microscopic differences, probably, in the structure of the cell wall.

Distribution of coniferin in freeze-fixed stem of Ginkgo biloba L. by cryo-TOF-SIMS/SEM.

To clarify the role of coniferin in planta, semi-quantitative cellular distribution of coniferin in quick-frozen Ginkgo biloba L. (ginkgo) was visualized by cryo time-of-flight secondary ion mass spectrometry and scanning electron microscopy (cryo-TOF-SIMS/SEM) analysis. The amount and rough distribution of coniferin were confirmed through quantitative chromatography measurement using serial tangential sections of the freeze-fixed ginkgo stem. The lignification stage of the sample was estimated using microscopic observations. Coniferin distribution visualized at the transverse and radial surfaces of freeze-fixed ginkgo stem suggested that coniferin is stored in the vacuoles, and showed good agreement with the assimilation timing of coniferin to lignin in differentiating xylem. Consequently, it is suggested that coniferin is stored in the tracheid cells of differentiating xylem and is a lignin precursor.

Function and structure of leaves contributing to increasing water storage with height in the tallest Cryptomeria japonica trees of Japan

Key messageInCryptomeria japonica, transfusion tissue in leaves may have functions of water storage and supply, which could compensate for hydraulic constraints with increasing height.AbstractThe tallest trees of Cryptomeria japonica occur in climatic regions similar to the world’s tallest trees. We hypothesized that tall C. japonica trees would have evolved adaptive mechanisms to overcome height growth limitation. Here, we focused on foliar water storage, a mechanism recently discovered in Sequoia sempervirens. In C. japonica, leaf water potential at turgor loss did not change with height or light availability, while leaf hydraulic capacitance and succulence (water content per leaf surface area) increased, suggesting hydraulic compensation. Plasticity of leaf morphology could contribute to avoiding negative effects of height on photosynthesis. We also focused on the structure and function of transfusion tissue in leaves and its role in water storage and supply. Cross-sectional area of transfusion tissue increased with height, whereas that of xylem was constant. We confirmed that water flowed from vascular bundle to mesophyll via the transfusion tissue. Cryo-scanning electron microscopy images of leaf cross sections showed that transfusion cells were flattened, but not fully dehydrated when leaf water potential decreased in situ and by experimental dehydration, and cell deformation was more marked for treetop leaves than for lower-crown leaves. The shape of transfusion cells recovered at predawn as well as after experimental rehydration. As in S. sempervirens, transfusion tissue of C. japonica may function as a hydraulic buffer, absorbing and releasing water according to leaf water status. Anatomical and hydraulic properties contributing to foliar water storage may be an adaptive mechanism acquired by tall Cupressaceae trees to overcome the hydraulic constraints on physiological function with increasing height.