Xylem Cavitation in Nodes and Internodes of Whole Chorisia insignis H.B. et K. Plants Subjected to Water Stress: Relations Between Xylem Conduit Size and Cavitation

Measurements of cavitation occurring in xylem conduits of differentstem parts in whole Chorisia insignis H.B. et. K. plants subjectedto water stress are reported. Pre-stressed plants were shownto undergo cavitation over 10 times greater than watered ones.The most vulnerable parts of plants were one-year-old twigswhere cavitation reached a peak of over 50 acoustic emissions(AE) min^–1 while in two-year-old twigs AE min^–1were about one half this value. Stem zones were found wherecavitation was typically very low even during water stress:these were one-year-old nodes and junctions where branches meet.Measurements of the inside diameters of xylem conduits and distributionof conduit ends in stem parts where AE were detected, showedthat nodes have a significantly larger percentage of narrowxylem conduits than internodes. Similar ‘constricted zones’were found injunctions with respect to two-year-old twigs. Hereabout 50 per cent of the xylem conduits were as narrow as 20to 50 µm in diameter. The distribution of xylem conduitends show about 3 per cent of them ending in the nodes and 1per cent in the internodes of one-year-old twigs. About 11.6per cent of xylem conduits end in the junctions and about ahalf in two-year-old internodes. Our data would give furtherexperimental evidence to the functional concept of ‘plantsegmentation’ into zones (internodes) more efficient inwater conduction, i.e. with wider xylem conduits but more vulnerableto cavitation and others (nodes and junctions) with oppositecharacteristics. Chorisia insignis, acoustic emissions, water stress, nodes, internodes, xylem conduit size, vessel ends     

Root hydraulic conductance of six forest trees: possible adaptive significance of seasonal changes

ABSTRACT

Root hydraulic conductance (K_R was measured in terms of the ratio of volume flow through roots (F) and to the pressure (P) driving the flow in six forest trees growing in habitats characterized by different water availabilities Le. Acer campestre L., Castanea sativa Miller, Fraxinus ornus L., Fraxinus oxycarpa Bieb., Ceratonia siliqua L. and Olea oleaster Hoffmg. et Link. Measurements were made in May, August and November 1996. K_R as normalized for unit leaf surface area (K_RL), was higher in species growing in humid environments (A. campestre and C. sativa) than in others (C. siliqua and O. oleaster) typical of aria zones. A. campestre and C. sativa showed declining K_RL values from spring to autumn while the latter had highest K_RL values in summer. This is in agreement with the typical drought avoidance strategy of C. siliqua which is based on large water losses balanced by equal water uptake from the soil. Plots of F and of A (leaf surface area) to K_RL as well as annual percent changes in F, A_L and K_RL suggest that changes in K_RL are mainly due to analogous changes in F, except for O. oleaster where opposite balanced changes in F and A_L contributed in maintaining the K_RL constant from August to November.     

Circadian regulation of leaf hydraulic conductance in sunflower (Helianthus annuus L. cv Margot)

The circadian regulation of leaf hydraulic conductance (K_leaf) was investigated in Helianthus annuus L. (sunflower). K_leaf was measured with an high pressure flow meter during the light and dark period from plants growing at a photoperiod of 12 h. K_leaf was 4.0 e−4 kg s⁻¹ m⁻² MPa⁻¹ during the light period (LL) and 30–40% less during the dark period (DL). When photoperiod was inverted and leaves were measured for K_leaf at their subjective light or dark periods, K_leaf adjusted to the new conditions requiring 48 h for increasing from dark to light values and 4 d for the opposite transition. Plants put in continuous dark showed K_leaf oscillating from light to dark values in phase with their subjective photoperiod indicating that K_leaf changes were induced by the circadian clock. Several cuts through the minor veins reduced leaf hydraulic resistance (R_leaf) of both LL and DL to the same value (1.0 e + 3 MPa m² s kg⁻¹) that equalled the vascular resistance (R_v). The contribution of the non-vascular leaf resistance (R_nv) to R_leaf was of 71.9% in DL and of 58.4% in LL. The dominant R_nv was shown to be reversibly modulated by mercurials, suggesting that aquaporins play a role in diurnal changes of K_leaf.     

Different vulnerabilities of Quercus ilex L. to freeze- and summer drought-induced xylem embolism: an ecological interpretation

Quercus ilex L. growing in the southern Mediterranean Basin region is exposed to xylem embolism induced by both winter freezing and summer drought. The distribution of the species in Sicily could be explained in terms of the different vulnerability to embolism of its xylem conduits. Naturally occurring climatic conditions were simulated by: (1) maintaining plants for 3h at ambient temperatures of 0, -1.5, -2.5, -5.0 and -11°C; and (2) allowing plants to dry out to ratios of their minimum diurnal leaf water potentials (Ψ₁) to that at the turgor loss point (Ψ_tlp) of 0.6, 0.9, 1.05, 1.20 and 1.33. The loss of hydraulic conductivity of one-year-old twigs reached 40% at -1.5°C and at Ψ₁/Ψ_tlP= 1.05. Recovery from these strains was almost complete 24 h after the release of thermal stress or after one irrigation, respectively. More severe stresses reduced recovery consistently. The percentages of xylem conduits embolized following application of the two stresses, were positively related to xylem conduit diameter. The capability of the xylem conduits to recover from stress was positively related to the conduit diameter in plants subjected to summer drought, but not in the plants subjected to winter freezing stress. The ecological significance of the different vulnerabilities to embolism of xylem conduits under naturally occurring climatic conditions is discussed.     

Sclerophylly and Plant Water Relations in Three Mediterranean Quercus Species

The possible role in drought resistance played by sclerophyllywas studied in the Mediterranean oaks Quercus ilex, Q. suberand Q. pubescens. Studies were conducted on leaves at 30, 50and 80% of their final surface area, as well as on mature leavesof the current year's growth in June and September and on 1-year-oldleaves. Leaves of different ages of the three species showed quite differentdegrees of sclerophylly (DS). Q. ilex leaves reached the definitiveDS of 1.75 g dm^–2 during leaf expansion; Q. pubescensleaves hardened at the end of their expansion, with a finalDS of 0.93 g dm^–2; Q. suber showed the lowest DS of 0.76g dm^–2. Leaf conductance to water vapour (g₁) of 1-year-old leaves ofQ. ilex, measured in the field, showed a duration of the g₁peak values about twice that of the other two species. The minimumleaf relative water content (RWC), however, was near the samein the three species, indicating that water loss was recoveredpartly by Q. ilex leaves. This was apparently due to the higherbulk modulus of elasticity (     

Activation of Satellite Cells Induced by Chronic Neostigmine Administration in the Rat

Muscle fibrillation has been suggested as a possible trigger for activation of satellite cells, a well known phenomenon associated with denervation. In order to test such a hypothesis fibrillation has been induced in normally innervated muscles by chronic administration of neostigmine and the response of satellite cells has been observed with a scanning electron microscope. The results show that satellite cells protrude from the profile of the muscle fiber, become partially separated from the latter, and align in rows. Elongated structures and presumable new muscle fibers are observed after 14 days of treatment. It is concluded that the overactivity of muscle fibers which is induced during fibrillation causes activation and differentiation of satellite cells. This result is consistent with that of a previous experiment showing that satellite cells are activated during acute increase in work-load.     

Relations between vulnerability to xylem embolism and xylem conduit dimensions in young trees of Quercus corris

Measurements of xylem conduit length and width and the distribution of xylem conduit ends were made in inter-nodes (I), nodes (N) and twig junctions (J) of 1-, 2- and 3-year-old twigs of plants of Quercus cerris L. Parallel measurements were also made of the loss of hydraulic conductivity of twigs subjected to pressure differentials across conduit pit membranes, equalling the leaf water potential at the turgor loss point. The loss of theoretical hydraulic conductivity was calculated as the ratio of i esivr⁴ (where r is the conduit radius) of the non-conducting conduits to that of all the conduits in the outermost wood ring of I, N and J. Stem zones such as 1-year-old nodes and junctions were localized with narrower and shorter xylem conduits and with higher percentages of conduit ends than internodes. Such ‘constricted zonesrsquo; were less vulnerable to embolism than internodes. Latewood conduits were consistently narrower, shorter and less vulnerable to embolism than earlywood ones. A positive relation therefore existed between conduit diameter and length and vulnerability to embolism. The overall vulnerability to embolism of Q. cerris plants is discussed in terms of xylem conduit width and length and of the distribution of conduit ends.     

Water storage in the wood and xylem cavitation in 1-year-old twigs of Populus deltoides Bartr.

The possible role of water expelled from cavitated xylem conduits in the rehydration of water-stressed leaves has been studied in one-year-old twigs of populus deltoides Bartr. Twigs were dehydrated in air. At desired values of leaf water potential (Ψ_l) (between near full turgor and -1.62 MPa), twigs were placed in black plastic bags for 1–2h. Leaf water content was measured every 3–5 min before bagging and every 10 min in the dark. Hydraulic conductivity and xylem cavitation were measured both in the open and in the dark. Cavitation was monitored as ultrasound acoustic emissions (AE). A critical Ψ_l value of -0.96 MPa was found, at which AE increased significantly while the leaf water deficit decreased by gain of water. Since the twigs were no longer attached to roots, it was concluded that water expelled from cavitated xylem conduits was transported to the leaves, thus contributing to their rehydration. Xylem cavitation is discussed in terms of a ‘leaf water deficit buffer mechanism’, under not very severe water stress conditions.