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Investigating survival. there is not any habitat in the world that would lack some moisture and lightgreat capacity for adaptation in green plants (summits of mountain, deep forest shade, below water surface, spots where it never rains,) plant ecophysiology: first interest to humans because of agriculture (seed selection and breeding of plants tolerant of or resistent to climatic extremes)further interest in studying plant survival in different habitats (survival = measure of relative fitnes29858
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1. Plants and Temperature Adaptability of (mostly) vascular plants to high and low temperatures and to the diurnal and seasonal periodicity of climatic factors
2. Investigating survival there is not any habitat in the world that would lack some moisture and light
great capacity for adaptation in green plants (summits of mountain, deep forest shade, below water surface, spots where it never rains,)
plant ecophysiology:
first interest to humans because of agriculture (seed selection and breeding of plants tolerant of or resistent to climatic extremes)
further interest in studying plant survival in different habitats (survival = measure of relative fitness)
3. Survival is the ability to tolerate local environmental conditions with the consequence of the selection of locally adapted forms
It is easy to study plants, they mostly
do not move from their habitats
plant distribution: dispersal limitations
are often more important than
survival capacities
DISTRIBUTION x SURVIVAL
distribution of plants is affected by historical, geographical and environmental factors enabling the
plants survival.
4. Adaptation (genotypic) Acclimatization (phenotypic) to have something special that increases the probability of survival of a certain genotype in its habitat
ADAPTATION has to be heritable
so we cannot speak about adaptation of one individuum
In such cases it is better to use the word
ACCLIMATIZATION (acclimation, hardening), which means individual adjustment to an environmental stress taking place in response to environmental conditions. Example: hardening of plants exposed to low temperatures
5. TOLERANCE:
physiological: endurance of a plant is measuredin culture with no competition and only one variable being altered at a time
ecological: response of a plant is examined under field conditions
The tolerance of certain habitats relates to Ellenbergs concept of a physiological and an ecological optimum for each plant genotype (taxon). The latter optimum is the result of competition, usually enabling a plant to materialize its physiological optimum only within certain limits.
6. Climatic boundaries CHILLING INJURY:
tropical species suffer at temperatures of 6-10 °C for leaves; so-called chill sensitive plants (Coffea arabica, Oryza sativa, Citrus, Musa, Passiflora). Flowers and fruits are also sensitive.
cellular dysfunctions, increase in membrane permeability, stopping of enzymatic activity.
7. Mediterranean distribution of the olive tree
chilling injury to fruits is of little importance to the plants survival, but the leaves are sensitive to chilling and that is a sufficient reason for the survival limitation
8. 2) FREEZING INJURY AND CRYOPROTECTION:
the most known frost boundaries: when moving inland from the Mediterranean littoral, frost-free areas defined by the olive distribution, limited by water loss in winter
frost resistance is genetically determined
hardening of plants to freezing temperatures is a long and stepwise process, while de-hardening can last only 2-4 days
hardening temperatures of +5 to 0°C enable a plant to withstand a moderate frost
in winter, frost tolerance can increase in 1-2 days, with a full effect in 10 days
dormant buds of leafy trees - the most resistant tissues
root tolerance is lesser than that of aerial parts
9.
ice crystals are not lethal as such if formed in the apoplast, the extent of frost damage is then dependent on desiccation resistance
membrane holes cause irreparable damage
rapid rate of thawing causes osmotic problems
photosynthesis is the most affected by freezing, mainly the photophosphorylation mechanisms are affected
membrane protection role of soluble sucrose when freezing temperatures occur (frozen potatoes, rose hips, sugar cane), trisaccharides are more effective than di-and monosaccharides
sugar alcohols are also effective (mannitol, inositol, sorbitol, glycerol)
halophytes use raffinose,which is not a part of primary metabolism
amino acids: accumulation of proline, increase from 2-4 % to 60 %.
10. 3) SUMMER WARMTH:
arctic species suffer from temperatures by 10 °C higher than is the mean summer temperature in their habitats
They do not suffer from heat injury, but the problem is related to carbon imbalance in the plants
These plants waste their carbohydrate reserves in summer and therefore are weak in the next spring
Heat injury occurs in most plants at temperatures higher than about 40 oC.
Extreme adaptation to high temperatures is found in thermophilous Cyanobacteria (70 to 85 oC) and Archaea (up to 95 oC) of hot springs
11. Periodicity Absorption rate of radiant energy in a place depends on its position in face of the Sun.
Available energy is an environmental factor which periodically changes. The fluctuations of energy supply are reflected in periodical temperature fluctuations
This periodicity affects all phenomena on the Earth, hence also any organisms life.
1. Climatic rhythms
2. Rhythms of biological processes reflect climatic rhythms
3. Growth periodicity synchronised with climatic rhythms
12. Climatic rhythms DIURNAL CHANGES (in plants)
1. day-night light changes lead to diurnal photoperiodicity
2. day-night temperature changes lead to diurnal thermoperiodicity
temperature changes lag behind changes in radiant energy input, temperature maxima differ in dependence of thihs input.
close to the equator: small differences in photoperiod while around the tropics: differences only of about 2 hours. Hence diurnal temperature fluctuations more important than the small seasonal ones
wide temperature fluctuations especially in the mountains, both tropical and temperate ones
SEASONAL CHANGES at higher latitudes day and night lengths change dramatically during the year
vegetative processes can be suppressed (dryness, cold)
13. Activity rhythms Diurnal light rhythm strongly influences plants.
Photosynthetic capacity decreases in permanent light.
Day-night temperature differences influence germination evolutionary adaptation
Best plant development when night T is by about 10-15 °C colder than day T
For cacti and desert plants 20 °C difference optimal, for temperate zone plants 5 to10 °C difference optimal
Exceptions:
young spruces: no differences = the best
tropical plants: only 3 °C differences
inverse thermoperiodicity, warm nights: e.g., Pinus ponderosa and violets
14. Growth and development seasonality LIFE CYCLE:
1) plants with continuous growth
short life cycles in many annuals, especially in ephemeral plants in deserts
annuals or perennials in tropics
2) plants with intermittent growth
growth at irregular intervals is safer (herbivores, parasites)
growth or stillstand is regulated by environmental factors, mainly radiation input and temperature. Examples: forest floor ephemeroids, C3 vs. C4 plants
16. 3) vegetative and winter dormancy periods alternate:
regularly changing seasons: changes in protoplasm, metabolic activity, developmental processes and tolerance of stress conditions
aitionomous break cycles without break, unfavourable environmental conditions enforce stillstand of metabolism cause breaks in growth (Senecio,
Cerastium, Capsella)
17. 4) winter dormancy in trees of cold regions
buds develop at the end of summer, during winter are dormant
trees defoliate
cambium is also dormant, other tree parts become resistant to cold and dehydration
Three phases of winter dormancy:
1. predormancy
- starts in buds before defoliation (decreasing daylenght poplar, oak, beech, birch, willow, hazel, maple, larch, spruce)
- low night temperature can replace short day (10 °C ash-tree, chestnut-tree, cherry-tree, lilac)
2. true dormancy
- starts in November, December, plants are unable to leave this rest period before end of dormancy
- prolonged cold temperature leads to phase 3 (0 °C or less for 3-4 weeks poplar, lime, maple, pine, fruit trees, grapewine)
18. 3. imposed dormancy
rest period is coming to an end, gibberellins, cytokinins and auxin increase
gene activation for basal metabolism, reserves mobilisation, biosynthesis and mitosis start
ends in February, then development and growing start, depending only on the weather
22. Growth synchronisation with climatic rhythms tropics: limited by decreased water availability in dry periods
others: activity synchronized with the vegetative period, photo- and thermoperiodism
latitudes > 40° = days are longer than nights during the whole growing season, adaptation = long-day with respect to production of new shoots, leaves and flowers,
a plant species is well acclimatized if the growing season is fully utilized, without risk of injury in the unfavourable season
24. Phenology indicator of weather characterisctics and climate changes
beginning and duration of developmental phases vary from year to year
phenology is interested in the processes of sprouting, flowering, fruit production and senescence
historical science
phenological dates: evidence of visible changes during the life cycle (start and end of the vegetation season, snow thawing, changes in colour of foliage)
26. phenological map of the start of lilac flowering in Europe as a signal of the start of spring
27. Dendrochronology shows annual growth rings and variability of climate
annual ring phenometry
phenometry = measuring
duration of cambial activity and the type of wood formed (early, late) are affected by environmental factors
spring wood indicates not only spring conditions but the nutritional status in the preceding year
late wood indicates factors slowing down shoot growth and senescence of leaves
30. End of general part: Adaptability of (mostly) vascular plants to high and low temperatures and to the diurnal and seasonal periodicity of climatic factors