Title: Many organisms are highly adapted to environmental temperature
1Many organisms are highly adapted to
environmental temperature
- Psychrophiles (lt 20?C)
- Mesophiles ( 20-35?C)
- Thermophiles ( 35-70?)
- Hyperthermophiles ( gt 70-110?C)
There is growing interest in understanding how
organisms adapt to extreme cold.
2Adaptations to Cold
- Can produce high levels of osmotic molecules
- amino acids (e.g., proline)
- special amino acids (e.g., glycine betaine)
- sugars (trehalose (glu-glu disaccharide),
mannitol - glycerol
- Protein (enzymes) sequences
- Higher levels of certain key enzymes
- Many cryophilic plants also adapted to excess
light stress (made worse by cold)
3Protein enzymes show evidence of adaptation to
low temperature
- Enzymes from psychrophilic organisms
- usually have a lower temperature optimum than
their mesophilic counterpart - are typically more thermolabile
- are usually more efficient catalysts
- are likely more flexible
4McMurdo Dry valley, Antartica
Glacier
Lake Bonney
5Red Snow
6Chlamydomonas nivalis
- Most common snow alga of Northern Hemisphere
Red Snow is the aplanospore form - May be more psychrotrophic than psychrophilic
(some isolates can grow at gt 20?C) - Red color from astaxanthin, a carotenoid,
cytoplasmic, protects chloroplast from UV light
7Cold Tolerance
- Different cultivars of the same species vary in
cold tolerance - suggests a genetic basis
- Temperate perennial plants "overwinter" to
survive - develop "cold hardiness - a quantitative genetic trait (many loci that are
additive) - All temperate perennials and many annuals can
"cold acclimate
8Cold acclimation (CA)
- CA is an inducible response, by cold (e.g., 4oC)
and sometimes other environmental cues (e.g.,
photoperiod) - Cellular processes are adjusted to increase
tolerance to cold - e.g., exposure of Arabidopsis to 4oC for 1 day
allows it to withstand -8 to -12oC - Also affected by developmental stage
- CA has genetic basis - also a quantitative trait
9How does cold damage plants?
- Ice formation
- Intracellular cells die from the expansion
- Extracellular not as bad, but cells can
collapse from dehydration - Direct cold damage
- Membranes plasma membrane and chloroplast
envelope probably main targets, cold and
dehydration alters biophysical properties - Enzymes - some are denatured by cold
10Membrane phospholipids change to gel-phase at low
temperature.
Inverted hexagonal phase can also form in the
cold due to dehydration.
11CA involves
- increased accumulation of certain small solutes
(amino acids and sugars) - help retain water
- help stabilize membranes and proteins
- Solutes usually neutral (zwitterions) or
uncharged molecules derived from polymers (Fig.
22.6) - changes in lipid composition of membranes
- changes in gene expression
12Membrane lipid changes in response to cold.
Degree of unsaturation of the fatty acids (i.e,
how many with a CC double bond) increases at
lower temperature. Relative ratios of different
phospholipids also changes, with more PE at
lower temperature. These changes lower the temp.
of the liquid?gel-phase transition.
PE phosphatidylethanolamine PC
phosphatidylcholine
13Effects of cold on gene expression comparison
with heat stress
- Plants exposed to cold synthesize new proteins
- Sizes of strongly induced proteins not as well
conserved as in heat shock, although some seen
in many species. - Housekeeping proteins continue to be
synthesized. - Some proteins synthesized transiently, whereas
some synthesized for weeks. - New proteins appear within a day after cold
shift.
14Microarray analysis of cold regulated genes in
Arabidopsis. Seki et al. (2001), Plant Cell 13,
61-72 1300 genes (as cDNAs) immobilized on a
microarray, which is hybridized to mRNAs from
normal and cold-stressed plants (after reverse
transcription into cDNA with a fluorescently
labeled nucleotide). Cy5- red,
induced Cy3-green, depressed Yellow- unchanged
15Genes induced by cold
- Many of unknown function, but some interesting
ones - Lea(s) also expressed in seeds before
dehydration (protective?) - (Table 22.2 five groups of Leas)
- Antifreeze proteins - (e.g., kin1 - similar to a
fish antifreeze protein), prevent or limit ice
formation, some are extracellular - other hydrophilic proteins (e.g., Cor proteins)
- Proteases
- Heat shock protein
- RNA-binding proteins
- Other regulatory proteins (transcription factors,
Ca2-binding proteins, etc.) - Appearance of many of these gene products
correlate with CA! - Over-expression of some have produced greater
freezing tolerance.
16Regulation of Cold-induced genes
- Transcriptional and post-transcriptional
regulation have been noted - Many cold-regulated genes contain the
DRE/C-repeat element in their promoters - DRE elements bound by proteins, CBF/DREB1
- activate transcription from a DRE element in
yeast - DNA-binding domain homologous to apetala2
17Over-expression of CBF1 in Arabidopsis increased
expression of cold-related (COR) genes and
freezing tolerance.
18Role of ABA (stress hormone)
- ABA Abscisic acid, phytohormone induced by
wilting, closes stomata by acting on guard cells
- Positive correlation between CA and ABA
- Treat plants with ABA, and they will be somewhat
cold hardened - possibly cold induces ABA, which induces genes?
- However, ABA does not induce all genes that cold
will. - Conclusion there are ABA-regulated and non-ABA
regulated changes that are induced by cold.
19Possible pathway for gene regulation by cold
Cold ? Ca 2 uptake ? activates protein
kinase(s) ? phosphorylation of regulatory
proteins (e.g., transcription factors) ? changes
in gene expression
20Plants vary in ability to tolerate flooding
- Plants can be classified as
- Wetland plants (e.g., rice, mangroves, Hydrilla)
- Flood-tolerant (e.g., Arabidopsis, maize, wheat)
- Flood-sensitive (e.g., soybeans, peas, tomato)
- involves developmental/structural, cellular and
molecular adaptations
21Pneumatophores weird roots In Mangroves For
gas exchange.
Fig. 22.20
22Flooding causes anoxia and an anaerobiotic
response in roots.
Maize Fig. 22.23
23ANAEROBIOSIS (low oxygen stress)
- mostly studied in maize and recently Arabidopsis
- roots can become anoxic when flooded
- Must shift carbohydrate metabolism from
respiration to anaerobic glycolysis - protein synthesis affected
24Aerobic Anoxic
Protein synthesis in aerobic versus anoxic maize
root tips. 5-hour labeling with 3H-leucine and
2-D gel electrophoresis.
Fig. 22.30
25Protein synthesis changes
- Dramatic
- slow response (hours)
- results in selective synthesis of 10-20
proteins - Response in two phases
- phase I (first few h) mainly a 33 kDa (ADH)
protein synthesized - phase II (12- 48h) 20 proteins dominate
synthesis - mRNAs for other proteins there but not translated
well!
26Anaerobic proteins (ANPs)
- Many of the ANPs are enzymes in or associated
with glycolysis and fermentation (examples) - UDP-sucrose synthetase
- glucose-phosphate isomerase
- pyruvate decarboxylase
- alcohol dehydrogenase I and II
- Already being synthesized but rate increases
- Anaerobic response of roots similar in other
species examined (cotton, soybeans, etc.) - Some other tissues also show it, but not leaves
27Roots get sucrose from leaves during the day. At
night, they break down stored starch.
28ADH is one of the most prominent ANPs It is a
dimer with 2 main isozymic forms
29Regulation of ADH1 has been studied.
Increased transcription and efficient translation
Fig. 22.32
30- How is translational control achieved?
- Mechanism not yet clear, but phosphorylation of
eIF4E (cap binding protein) and ribosomal
protein S6 is induced by anoxia in maize roots. - May explain repression of translation of the
cellular mRNAs other than ANP mRNAs. - Other questions
- What is the oxygen sensing mechanism?
- How does the low oxygen signal control the
transcription factor(s) for the ANP genes?