Chronologies of earlywood vessels and latewood width disentangle climate drivers of oak growth in a mild oceanic region

This paper reviews the development of xylem vessels in ring-porous dicots and the corresponding leaf phenology. Also included are our original observations on the time-course of vessel element growth, secondary wall deposition, and end wall perforation in the deciduous hardwood Kalopanax septemlobus. Different patterns of xylem growth and phenology serve different strategies of the species for adaptation to seasonal climates. Trees with ring-porous xylem form wide earlywood vessels (EWV) in spring and narrow latewood vessels in summer. The wide EWV become embolized or blocked with tyloses by the end of the growing season while the narrow vessels may remain functional for many years. The co-occurrence of wide and narrow vessels provides both efficiency and safety of the water transport as well as a potentially longer growing season. It has for a long time been assumed that EWV in ring-porous hardwoods are formed in early spring before bud burst in order to supply sap to growing leaves and shoots.However, the full time-course of development of EWV elements from initiation of growth until maturation for water transport has not been adequately studied until recently. Our observations clarify a crucial relationship between leaf maturation and the maturation of earlywood vessels for sap transport. Accumulated new evidence shows that EWV in branches and upper stem parts develop earlier than EWV lower in the stem. The first EWV elements are fully expanded with differentiated secondary walls by the time of bud burst. In lower stem parts, perforations in vessel end walls are formed after bud burst and before the new leaves have achieved full size. Therefore, the current-year EWV network becomes functional for water transport only by the time when the first new leaves are mature.

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Patterns of distribution and abundance of larval phosichthyidae (actinopterygii, stomiiformes) in southeastern Brazilian waters

Brazilian Journal of Oceanography ◽

10.1590/s1679-87592011000300002 ◽

2011 ◽

Vol 59 (3) ◽

pp. 213-229 ◽

Cited By ~ 1

Author(s):

Cássia Gôngora Goçalo ◽

Mario Katsuragawa ◽

Ilson Carlos Almeida da Silveira

Keyword(s):

Vertical Distribution ◽

Water Column ◽

Vertical Migration ◽

Diel Vertical Migration ◽

Distribution Patterns ◽

Southeastern Brazil ◽

Patterns Of Distribution ◽

Oceanic Region ◽

Brazil Current ◽

Horizontal And Vertical Distribution

Horizontal and vertical distribution patterns and abundance of larval phosichthyids were investigated from oblique and depth-stratified towns off Southeastern brazilian waters, from São Tomé cape (41ºW.; 22ºS.) to São Sebastião island (45ºW.; 24ºS.). The sampling was performed during two cruises (January/2002 -summer; August/2002 -winter). Overall 538 larvae of Phosichthyidae were collected during summer and 158 in the winter. Three species, Pollichthys mauli, Vinciguerria nimbaria and Ichthyioccoccus sp. occurred in the area, but Ichthyioccoccus sp. was extremely rare represented by only one specimen, caught in the oceanic region during the summer. Geographically, larval were concentrated in the oceanic region, and vertically distributed mainly between the surface and 80 m depth in the summer and winter. Larvae were more abundant during the night, performing a diel vertical migration in the water column. The results suggest that the meandering and eddies of Brazil Current play important role on the transport and distribution patterns of larval phosichthyids over the oceanic and neritic area in the Southeastern Brazil.

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Timeline of Leaf and Cambial Phenology in Relation to Development of Initial Conduits in Xylem and Phloem in Three Coexisting Sub-Mediterranean Deciduous Tree Species

Forests ◽

10.3390/f11101104 ◽

2020 ◽

Vol 11 (10) ◽

pp. 1104

Author(s):

Jožica Gričar ◽

Andreja Vedenik ◽

Gregor Skoberne ◽

Polona Hafner ◽

Peter Prislan

Keyword(s):

Tree Species ◽

Leaf Development ◽

Radial Growth ◽

Secondary Growth ◽

Growth Patterns ◽

Deciduous Tree ◽

Cambial Cell ◽

Cell Production ◽

Sieve Tubes ◽

Earlywood Vessels

It is unclear how the anticipated climate change will affect the timing of phenology of different tree organs/tissues and thus the whole-tree functioning. We examined the timing of leaf phenology and secondary growth in three coexisting deciduous tree species (Quercus pubescens Willd., Fraxinus ornus L. and Ostrya carpinifolia Scop) from a sub-Mediterranean region in 2019. In addition, we investigated the relationship between leaf and cambial phenology and the onset of the potential functioning of initial conduits, as determined by the completed differentiation process (vessels) or final size (sieve tubes). For this purpose, leaf development was monitored and the microcores of cambium and the youngest phloem and xylem increments were repeatedly collected at 7–10-day intervals during the growing season. The results revealed differences in the timing of leaf development and seasonal radial growth patterns in spring among the studied tree species, depending on wood porosity. We found that cambial cell production started in all cases in the first half of March. However, in ring-porous Q. pubescens and F. ornus, radial growth in the stem occurred more than a month before buds were swollen, whereas in diffuse-porous O. carpinifolia, these two events were detected at almost the same time. The end of cambial cell production occurred earliest in F. ornus (mid-July) and two weeks later also in the other two species. The widest initial earlywood vessels and early phloem sieve tubes were found in Q. pubescens, the narrowest initial earlywood vessels in O. carpinifolia and the narrowest early phloem sieve tubes in F. ornus. This indicates differences in the efficiency of conducting systems among the studied species. This novel approach of studying phloem phenology and anatomy in relation to leaf and xylem development contributes to a better understanding of how different tree species adapt their structure of secondary vascular tissues in response to environmental change.

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Biodiversity and livelihood in land-use gradients in an era of climate change - outline of a Nepal-Swiss research project

Botanica Orientalis Journal of Plant Science ◽

10.3126/botor.v7i0.4368 ◽

1970 ◽

Vol 7 ◽

pp. 7-17 ◽

Cited By ~ 4

Author(s):

Christoph Scheidegger ◽

Michael P Nobis ◽

Krishna K Shrestha

Keyword(s):

Land Use ◽

Regional Climate ◽

Population Data ◽

Forest Fragments ◽

Conservation Area ◽

Study Region ◽

Epiphytic Lichen ◽

Oceanic Region ◽

Precipitation Regimes ◽

Different Levels

The Swiss National Science Foundation has recently granted a project where we propose to study how different levels of land-use intensity (from primeval forests to arable fields) and climate do affect biodiversity on the southern slope of the Nepalese Himalayas. We will investigate replicated land-use gradients at various altitudes in three regions with a different regional climate, and in particular, different levels of seasonal precipitation. Our core study region will be the Manaslu Conservation Area characterized by an oceanic climate and this region will be compared to a hyper-oceanic region in Annapurna Conservation Area and a semi-oceanic region of the Sagarmatha (Everest) region. By using a quasi-experimental landscape approach organisms will be investigated in six valleys covering different precipitation regimes, altitudinal gradients over 1600 m representing different temperatures, and four land use types ranging from closed forests to open landscapes. These organisms will include plants, lichens, mushrooms, butterflies and birds. Population data of Red Listed mammals (flagship species) will be collected during the project by local authorities. The functional connectivity of forest fragments along land-use and climate gradients will be assessed for two intensively studied species, the epiphytic lichen Lobaria pindarensis and the tree species Taxus wallichiana. DOI: 10.3126/botor.v7i0.4368Botanica Orientalis – Journal of Plant Science (2010) 7: 7-17

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Distribution of cloudiness and categorization of rainfall types based on INSAT IR brightness temperatures over Indian subcontinent and adjoining oceanic region during south west monsoon season

Journal of Atmospheric and Solar-Terrestrial Physics ◽

10.1016/j.jastp.2017.06.017 ◽

2017 ◽

Vol 161 ◽

pp. 76-82 ◽

Cited By ~ 1

Author(s):

P. Vijaykumar ◽

S. Abhilash ◽

K.R. Santhosh ◽

B.E. Mapes ◽

C. Suvarchal Kumar ◽

...

Keyword(s):

Indian Subcontinent ◽

Monsoon Season ◽

Brightness Temperatures ◽

South West ◽

Oceanic Region ◽

South West Monsoon ◽

West Monsoon

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Vessel element development in the earlywood of red oak (Quercus rubra)

Canadian Journal of Botany ◽

10.1139/b69-288 ◽

1969 ◽

Vol 47 (12) ◽

pp. 1965-1971 ◽

Cited By ~ 44

Author(s):

John C. Zasada ◽

Robert Zahner

Keyword(s):

Shoot Elongation ◽

Main Stem ◽

Red Oak ◽

Vessel Element ◽

Oak Trees ◽

Vessel Elements ◽

Bark Peeling ◽

Extreme Care ◽

Earlywood Vessels ◽

Cell Zone

Earlywood formation was observed in 60-year-old forest-grown red oak trees in southern Michigan. Extreme care in removing samples from the cambial region of the main stem at 1.4 m and 18 m, and from small branches at about 24 m, permitted the following conclusions. First vessel elements were initiated in the second or third xylem derivative radially removed from the previous year's latewood, possibly in overwintering derivatives, simultaneously throughout the bole and branches of the tree, some 2 weeks before bud enlargement. Vessel elements enlarged first in the tangential dimension (to about 200 μ.) within a few days after initiation of differentiation. Enlargement in the radial direction required up to 2 weeks to grow 300 μ, occurring as the entire xylem mother cell zone was displaced outward by cambial growth to either side—tangentially—of the vessel element. The duration of earlywood formation was about 10 weeks, while the duration of shoot elongation was less than 2 weeks. First earlywood vessels were fully mature about 5 weeks after initiation, coinciding with the unfolding of first leaves. All foliage was mature several weeks before complete maturation of later formed earlywood vessels. Detailed stem analysis and bark peeling studies revealed that stem sections clear of branching contained few lateral junctions between axial vessels. There were many such junctions where twigs joined larger limbs and where limbs joined the main stem; all such junctions were between adjacent vessels from the same limb.

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