[14-16] - Floods, Seeds and Stomata (Nuhse Lectures) Flashcards
Where is rice predominantly produced, and what are the different forms of rice production?
The vast majority is produced in Asia:
- IRRIGATED LOWLAND PRODUCTION
-> 75% of production
-> 2-3 harvests per year
-> Requires 3000-5000L water per kg rice
-> Around 24-30% of global freshwater use annually - RAINFED LOWLAND RICE PRODUCTION
-> No constant supply and/or control of irrigation - more subject to flooding and drought
-> Usually just 1 harvest per year
-> More variable yields - RAINFED UPLAND RICE PRODUCTION
-> Fields are never flooded, aerobic soil conditions throughout
-> Low, variable yields - often used by subsistence farmers with little or no external inputs
Briefly summarise the two strategies shown by submergence tolerant strains of rice to cope with flooding
ESCAPE and QUIESCENCE
Escape: rapid growth (internode elongation) to ensure some tissue remains above the water, so that O2 can be fed to the rest of the plant
Quiescence (also known as low-oxygen quiescence syndrome): involves suppression of shoot elongation to preserve nutrients (such as carbohydrates) for as long as possible (up to 10-14 days), with the aim of minimising wasted resources during the submergence period, and then using the conserved carbohydrates to resume growth during desubmergence
Explain the ESCAPE strategy in deepwater rice and the molecular mechanism that underpins it
The escape strategy relies on the gaseous plant hormone ETHYLENE
During normal conditions, ethylene escapes into the air; however, submergence prevents it from escaping, causing it to accumulate in plant tissues and induce downstream responses via another hormone (GIBBERELLIN)
Specifically, the ethylene response factors snorkel1/2 are though to promote ABA degradation, thereby increasing GA activity and downstream responses; the Della proteins SLR1 and SLRL1 are also inhibited, allowing GA responses to be activated
-> Evidence that ethylene-induced responses are more complicated: ethylene also induces the ethylene-responsive TF OsEIL1a, which upregulates the GA biosynthesis gene SD1, thereby rapidly increasing GA concentration and promoting internode elongation
GA then appears to act via activation of ACE1 and inhibition of DEC1 to induce internode elongation, which can help rice plants survive flooding, BUT also reduces yield from 6-8t/ha to just 1 t/ha (as spindly plants expend more resources on elongation and thus produce lower yields)
When water rises VERY quickly, rice sometimes cannot grow fast enough for the escape strategy to be effective
Explain the QUIESCENCE strategy in rice and the molecular mechanism that underpins it
Submergence-tolerant cultivars (as opposed to deepwater rice) show a range of traits that allow them to withstand complete submergence during flash floods:
Energy maintenance:
-> Minimum elongation
-> Carbohydrate level in stem
-> Optimum fermentation
-> Underwater photosynthesis
Protection:
-> Efficient AOS scavenging
-> Low ethylene synthesis OR sensitivity
The most submergence-tolerant races from India have been collected and screened since the 1970s.
-> The FR13A landrace is submergence tolerant (and shows dominance)
-> The Sub1 locus was identified in 2006, and accounts for around 70% of variation in submergence tolerance
-> This is conferred by the Sub1A-1 gene, and ethylene response factor (the Sub1A gene is very similar to SNORKEL1/2 despite having the opposite effect)
Pathway:
Ethylene activates SUB1A, which STABILISES SLR1 + SLRL1 (which then inhibit GA responses) and also inhibits ethylene (negative feedback)
What was the variety of rice that was bred to be high-yielding but also submergence tolerant?
Swarna-Sub1 rice was developed in the 2000s by repeatedly crossing the submergence tolerant (but low yielding) Sub1 variety with the high yielding (but flood-prone) Swarna variety, until a variety was produced with a very similar genome to Swarna, but retaining the Sub1 gene [Marker-assisted selection, MAS]
This allowed the Sub1 trait to be rapidly introgressed into Swarna without the need for GM (which would have required regulation and been viewed sceptically by farmers)
The Swarna-Sub1 variety now accounts for over 25% of rice planted in India -> popular because high-yielding, flooding-insensitive, AND produced grains with a more favourable colour for rituals
What allowed the ethylene signalling pathway to be discovered?
The TRIPLE RESPONSE:
- The addition of ethylene induces a distinct Triple Response
-> an exaggerated Apical Hook
-> a short root
-> a short hypocotyl
By screening for mutants in this pathway and these specific responses, it was possible to identify genes involved in ethylene responses
What was the first ethylene response mutant to be discovered, and what did it reveal about the underlying mechanism?
etr1 (EThylene Response mutant)
-> A mutation in a gene similar to prokaryotic two-component sensors - previously, no such response regulators had been discovered in eukaryotes (a similar one has since been discovered in tomatoes, never-ripe)
Mechanism:
-> In total, there are 5 ethylene receptors in Arabidopsis
-> Etr1, Etr2, Ers1 (ethylene response sesnor 1), Ers2 and Ein4 (ethylene-insensitive 4)
-> These all reside in the ER and can form heteromeric complexes
-> Need to look at second-most-important mutant to fully piece together the mechanism
What was the second key ethylene response mutant that allowed more of the underlying mechanism to be understood?
ctr1 (constitutive triple response)
-> Mutation in a Raf-like kinase
-> CTR1 is a negative regulator of ethylene signalling
Whole pathway:
-> In the ABSENCE of ethylene, the receptors (Etr1 etc.) are active, and activate CTR1, which in turn inhibits downstream ethylene responses
-> However, in the PRESENCE of ethylene, the receptors bind it and are inactivated, meaning CTR1 is also inactive (therefore, ethylene responses are NOT inhibited, and can be induced
Note on mutants:
-> A missense mutation at the binding site of one of these receptors prevents ligand binding and makes the receptor insensitive to ethylene - this can lead to suppression of responses even in the presence of ethylene
-> Meanwhile, disruptions in the regulatory domains of at least three ethylene receptors can lead to receptor INactivation, even in the absence of ethylene, leading to a constitutive ethylene response
-> For a similar reason, LoF mutations in CTR1 lead to a constitutive ethylene response, as the pathway cannot be inhibited
What was the next protein mentioned after the ethylene receptors and CTR1, which explains how CTR1 is linked to downstream responses?
EIN2 - a positive regulator of ET signalling
LoF mutants in EIN2 are ethylene INsensitive, showing that it normally has a positive role. It has 12 membrane-spanning domains and was known to be downstream of CTR1, but how this signal transduction occurred was unknown until 2012
-> Active CTR1 phosphorylates and targets the C-terminal domain of EIN2 for degradation at the 26S proteasome, along with the TFs EIN3 and EIL1
-> When CTR1 is INactive (either due to ethylene binding at the receptor, or due to LoF mutations in CTR1), EIN2 is not phosphorylated, and the C-terminal region (along with EIN3/EIL1) is cleaved, translocates to the nucleus and promotes ethylene responsive genes via ERF1 (a member of the ERF TF subfamily)
Summarise the key steps in Ethylene Biosynthesis
- Methionine is converted to S-adenosylmethionine (AdoMet) via AdoMet Synthase
- AdoMet is converted to ACC (1-aminocyclopropane-1-carboxylic acid) via ACC Synthase (ACS)
- ACC is converted to ETHYLENE via ACC Oxidase (ACO)
Explain which enzyme in the Ethylene Biosynthesis Pathway is tightly regulated (and was explained in the lecture)
ACC Synthase (ACS):
-> ACS is highly unstable, and is constantly synthesised and degraded again, keeping ethylene levels low under normal conditions
-> Phosphorylation of the ACS C-terminus can prevent interaction with the 26S proteasome, thus stabilising ACS
-> This can happen in response to wounding or pathogen attack (via MAPK) or abiotic stress such as cold (via CDPK)
This is how ethylene levels are increased in response to biotic or abiotic stresses such as these
Summarise the wide range of whole-plant processes in which ethylene is involved
-> Shoot + Root Elongation
-> Flooding responses (e.g., aerenchyma formation, leaf epinasty, deepwater rice elongation)
-> Pathogen Responses
-> Reproductive Development (e.g., sex determination in cucumbers, petal senescence, fruit ripening)
This is demonstrated by the fact that ethylene blockers (e.g., silver thiosulfate and CACP) promote longevity in cut flowers; also the fact that ethylene production peaks before ripening in climacteric fruit, and that inhibiting ethylene synthesis can slow down fruit ripening
Very briefly describe how fertilisation occurs in plants
Double fertilisation:
-> One sperm cell fuses with the egg cell to form the zygote, while the other fuses with the nuclei of the central cell to form the triploid (3n) endosperm
(The developing embryo remains tethered to the plant by a suspensor)
When does seed maturation begin, what are the key changes that occur, and which hormone plays a central role in this process?
It begins after the completion of embryo development (i.e., once cell division stops)
The four key changes are:
-> Transition from maternal to filial control (i.e., the embryo takes over control of development from the maternal tissue)
-> Accumulation of storage compounds (e.g., starch, proteins, fat - depends on the plant/seed type)
-> Establishment of primary dormancy (the first step of preparing the seed for desiccation)
-> Acquisition of desiccation tolerance (LEA genes established), then desiccation
In terms of fresh weight:
STAGE 1: Weight remains constant but rapid cell division and differentiation are occurring
STAGE 2: Water weight increases, peaks, then starts to decrease while dry weight increases (cell expansion and accumulation of storage compounds during this time)
STAGE 3: Water weight decreases as seeds prepare for desiccation
ABSCISIC ACID (ABA) plays a central role in this process
What are the key changes/phases that a seed undergoes following maturation, and how does this vary between different types of seeds?
Eventually, germination will begin, but this depends on the seed type:
-> Orthodox seeds remain dormant for a while, then lose dormancy but remain quiescent (a resting state with low metabolism), until suitable environmental conditions allow germination
-> Evolution has selected for some seeds to remain dormant for longer (so that, even if a catastrophic event kills all the germinated seeds, the dormant ones are not lost)
-> Recalcitrant (“unorthodox”) seeds are NOT tolerant to drying out and do not have long term viability, they must germinate soon after maturation [e.g., mango, lychee, avocado, cocoa]
-> Vivipary occurs when induction of dormancy fails and immature seeds germinate while on the mother plant (normal for mangroves, mutants in other species)
In PHASE 1 of germination (imbibition):
-> seedling swells, fresh weight increases
-> this occurs by simple physical uptake of water
In PHASE 2 of germination (lag):
-> intense metabolic activity
-> mitochondrial activation, protein synthesis, gene expression, hydrolysis of cell walls, breakdown of storage products, etc.
In PHASE 3 of germination:
-> continued water uptake
-> weakening of endosperm cell walls
-> seed coat + endosperm rupture; radicle emergence due to cell expansion
