Opposite Effects of Daylength and Temperature on Flowering and Summer Dormancy of Poa bulbosa

doi:10.1093/aob/mcl021

AOBPreview originally published online on February 8, 2006
Annals of Botany 2006 97(4):659-666; doi:10.1093/aob/mcl021

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Opposite Effects of Daylength and Temperature on Flowering and Summer Dormancy of Poa bulbosa

MICHA OFIR^* and JAIME KIGEL

Institute of Plant Sciences and Genetics in Agriculture, Faculty of Agricultural, Food and Environmental Quality Sciences, Hebrew University of Jerusalem, Rehovot, PO Box 12, 76100, Israel

^* For correspondence. E-mail ofir{at}agri.huji.ac.il or mofir{at}zahav.net.il

Received: 29 September 2005 Returned for revision: 21 November 2005 Accepted: 20 December 2005 Published electronically: 8 February 2006

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

• Background and Aims The timing of flowering and summerdormancy induction plays a central role in the adaptation ofMediterranean geophytes to changes in the length of the growthseason along rainfall gradients. Our aim was to analyse therole of the variation in the responses of flowering and summerdormancy to vernalization, daylength and growth temperaturefor the adaptation of Poa bulbosa, a perennial geophytic grass,to increasing aridity.

• Methods Flowering and dormancy were studied under controlleddaylengths [9 h short day (SD) vs. 16 h long day (LD)] and temperatures(16/10, 22/16 and 28/22 °C day/night) in four ecotypes originatingin arid, semi-arid and mesic habitats (110, 276 and 810 mm rainyear^–1, respectively) and differing in flowering capacityunder natural conditions: arid–flowering, semi-arid–flowering,semi-arid–non-flowering and mesic–non-flowering.

• Key Results Flowering and dormancy were affected in oppositeways by daylength and growth temperature. Flowering occurredalmost exclusively under SD. In contrast, plants became dormantmuch earlier under LD than under SD. In both daylengths, hightemperature and pre-chilling (6 weeks at 5 °C) enhanceddormancy imposition, but inhibited or postponed flowering, respectively.Induction of flowering and dormancy in the different ecotypesshowed differential responsiveness to daylength and temperature.Arid and semi-arid ecotypes had a higher proportion of floweringplants and flowering tillers as well as more panicles per plantthan mesic ecotypes. ‘Flowering’ ecotypes entereddormancy earlier than ‘non-flowering’ ecotypes,while the more arid the site of ecotype origin, the earlierthe ecotype entered dormancy.

• Conclusions Variation in the flowering capacity of ecotypesdiffering in drought tolerance was interpreted as the resultof balanced opposite effects of daylength and temperature onthe flowering and dormancy processes.

Key words: Poa bulbosa, bulbous blue-grass, daylength, temperature, flowering, summer dormancy, aridity, ecotype

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

The timing of phenological transitions during the life cycleof geophytes inhabiting regions with seasonal changes in growthconditions is of key importance for their survival and reproduction.These transitions, i.e. activation and sprouting of regenerationbuds, flowering and dormancy, are usually caused by seasonalchanges in environmental factors, such as daylength and temperature(LeNard and De Hertogh, 1993). We argue that ecotypic adaptationof geophytes along gradients of climatic conditions, such asincreasing aridity, involves variation in the timing of floweringand dormancy onset due to changes in the responsiveness of theseprocesses to the relevant regulatory environmental factors.Here we study this hypothesis in ecotypes of Poa bulbosa occurringalong a steep rainfall gradient and differing in drought tolerance(Ofir and Kigel, 2003). Poa bulbosa is a summer-dormant, smallperennial grass geophyte, widely distributed in the Mediterraneanand adjacent phytogeographic regions (Davis, 1985). In regionswith a Mediterranean type of climate (i.e. mild, rainy wintersand dry, hot summers), its small bulbs re-sprout after the firstrains in the autumn. The plants grow and flower during the winterand produce new bulbs at the base of the tillers, just belowthe soil surface, as the plants become dormant at the end oftheir active growth phase, in early spring (Ofir and Kerem,1982; Ofir and Dorenfeld, 1992). In some populations, apomicticseeds and/or small vegetative propagules (i.e. bulbils) developin the inflorescences (Youngner, 1960; Heyn, 1962; Davis, 1985).Summer dormancy in P. bulbosa is induced by long days and acceleratedby high temperature (Ofir and Kerem, 1982), while pre-exposureto short days and low temperature enhances dormancy inductionby long days (Ofir and Kigel, 1999). A similar mode of environmentalcontrol of summer dormancy occurs in Allium cepa (Brewster,1990) and A. sativum (Kamenetsky et al., 2004). Flowering inP. bulbosa occurs relatively early during the growth season,in late winter, and is highly variable among and within populations,with flowering and non-flowering plants co-occurring in thesame population (Heyn, 1962; Ofir and Kerem, 1982; Ofir andKigel, 2003). In some populations, a high proportion of theplants flower, while in others flowering is absent or rare,and reproduction is mainly vegetative, by tillering and basaltiller bulbs. Since tillering ceases when plants become dormant,variation in the onset of dormancy directly affects floweringpotential, as well as the balance between seed and vegetativereproduction.

Previous work with P. bulbosa showed wide variation in the timingof dormancy imposition and in the flowering capacity of populationsalong a rainfall gradient (Ofir and Kigel, 2003). Furthermore,ecotypes showed a negative relationship between age at dormancyonset and flowering: dormancy was earlier and flowering capacitywas higher with increasing aridity at the site of populationorigin. Here we propose that this ecotypic variation in dormancyonset was due to changes in the responsiveness to long daysand increasing temperature, the main regulatory environmentalfactors leading to summer dormancy in P. bulbosa. On the otherhand, little information is available on the daylength and temperaturesrequired for flowering in P. bulbosa (Youngner, 1960), nor ondifferential responses of ecotypes varying in flowering capacityto daylength, temperature and vernalization. In most Festucoidperennial grasses from temperate regions, flowering has a dualinduction requirement: a primary induction by vernalizationand/or short days, and a secondary induction that requires atransition from short to long days and is enhanced by moderatelyhigh temperatures (Heide, 1994). However, a wide spectrum offlowering responses to daylength and vernalization has beenfound among annual and perennial populations of P. annua andin the related P. infirma and P. supina (Johnson and White,1997a, b; Heide, 2001), raising doubts about the nature of theenvironmental factors controlling flowering in P. bulbosa. Thus,the main goals of our research were (a) to study the effectsof vernalization, daylength and growth temperature on floweringand dormancy induction in ecotypes differing in flowering capacityand occurring along a rainfall gradient; and (b) to analyseecotypic differences in responsiveness of flowering and dormancyto the environmental factors controlling these processes.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Plant material
Populations of P. bulbosa L. were sampled along a North–South(latitudes 33°03' to 31°15') rainfall gradient (810–110mm rain year^–1) in Israel during April 2000 (Ofir andKigel, 2003). Collected clumps (‘parent plants’)were planted in loess soil in 4 L pots and kept outdoors underthe natural climate conditions in a net-house at the Facultyof Agriculture in Rehovot, Israel. The parent plants becamedormant every spring (March to April) and started active growthafter the first autumn rains (October to November). Floweringwas recorded for each parent plant during 3 years, from 2000to 2003. Populations differed in the degree of flowering inthe net-house and in their response to dormancy induction bylong days under controlled conditions: the percentage of floweringplants was higher and onset of dormancy was earlier, the morearid the site of population origin (Ofir and Kigel, 2003). Fromthis collection, four contrasting ecotypes from three sitesacross the rainfall gradient and differing in their floweringcapacity, i.e. consistent yearly flowering or lack of floweringin the net-house, were taken for this study (Table 1): (1) arid(110 mm rain year^–1), flowering ecotype (‘A–F’);(2) semi-arid (276 mm year^–1), flowering ecotype (‘SA–F’);(3) semi-arid (276 mm year^–1), non-flowering ecotype (‘SA–NF’);and (4) mesic (810 mm rain year^–1), non-flowering ecotype(‘M–NF’). In the semi-arid site, the floweringand non-flowering ecotypes co-occur. Three large parent plantswere chosen from each ecotype and 160–300 dry, dormantbulbs were separated from each parent plant in April 2003. Thesebulbs were dry stored in paper bags at 40 °C in the darkfor 6 weeks, to reduce dormancy and facilitate simultaneoussprouting after planting (Ofir, 1986).

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TABLE 1. Characterization of four P. bulbosa ecotypes differing in the rainfall at the site of origin, flowering capacity and dormancy: arid and flowering (‘A–F’); semi-arid and flowering (‘SA–F’), semi-arid and non-flowering (‘SA–NF’); and mesic and non-flowering (‘M–NF’)

Controlled experiment conditions
Differences among ecotypes in flowering and dormancy responsesto low temperature pre-treatment (i.e. pre-chilling), daylengthand growth temperature were studied under controlled environmentalconditions in a phytotron, in glass-covered growth rooms transmitting80 % of outside solar radiation (Ofir and Kigel, 2003

). Day/nightgrowth temperatures were 16/10, 22/16 and 28/22 °C, controlledwithin ± 0·5 °C. Relative air humidity duringthe day period was set to 64, 75 and 82 %, respectively, toensure the same vapour pressure deficit (0·66 kPa) atthe different growth temperatures. Day temperature and humiditywere maintained from 07:00 to 16:00 h. Changes between day andnight temperature and humidity were gradual, spanning 3 h. Thedaylengths used were short day (SD), 9 h (07:00–16:00h) of natural light, and long day (LD), 16 h (04:00–20:00)attained by extending the natural daylength with supplementarylighting (3–5 µmol m^–2 s^–1 PAR at plantlevel), using 75 W incandescent tungsten lamps (LM960 OsramGmbH, München, Germany). Plants were grown singly in 0·8L drained plastic pots, in a substrate of volcanic tuff gravel,vermiculite no. 4 and peat (2 : 1 : 1 v/v/v), irrigated alternatelywith 50 % Hoagland's nutrient solution and tap water, once every1–2 days to avoid salt accumulation.

Experimental design
A factorial experiment with a completely randomized design wascarried out with the following treatment combinations: fourecotypes, pre-chilling at 5 °C vs. non-chilled bulbs, followedby growth under SD or LD photoperiods, at 16/10, 22/16 and 28/22°C. In the low temperature pre-treatment, bulbs from eachparent plant were planted at 5 °C in a moist substrate (vermiculite–tuffgravel 1 : 1 v/v) for 6 weeks (pre-chilling, LT₆). The bulbssprouted during the low temperature treatment and were illuminatedfor 8 h daily with cool white fluorescent lamps (100 µmolm^–2 s^–1 PAR at plant level) until the end of thetreatment. In the control treatment (without pre-chilling, LT₀)the bulbs were dry stored at room temperature (20–25 °C)for 6 weeks. At the end of the pre-chilling and dry storageperiods, respectively, bulbs were transplanted singly to 0·8L pots in a wet substrate in the phytotron, at SD and LD atthe three growth temperatures. Eight to 12 daughter plants fromeach of the three parent plants, making up 24–36 replicates,were included in every treatment combination of ecotype, pre-chilling,photoperiod and growth temperature.

Flowering and dormancy parameters
A plant was considered as flowering when at least one of itstillers had an emerged panicle, and as dormant when most ofits leaves were yellowing and drying and most of its tillershad bulbs. Plant age at flowering and dormancy was recordedindividually for each plant. Plant age in LT₆ treatments wasmeasured from planting day in the phytotron of already sprouted,pre-chilled plants with 2·4 ± 0·1 leaves.Age in LT₀ plants was taken from day 7 after sprouting, whenplants had about two leaves, as in the pre-chilled plants. Dormantplants were routinely removed and the total number of tillersand proportions of bulbing tillers recorded. The cumulativepercentage of dormant LD plants vs. time was plotted for eachecotype, in each treatment combination. The rate of dormancyimposition was determined from the nearly linear portion ofthe resulting sigmoid curve, between one-sixth and five-sixthsof the final percentage of dormant plants. All linear regressionswere highly significant (r > 0·96, P < 0·01).In SD treatments, the proportions of flowering and dormant plantswere recorded at age 3 and 5 months (end of the experiment).The number of panicles per plant was recorded 5 months afterplanting.

Statistical analyses
Statistical analyses were carried out with JMP_IN (version 4·04SAS Institute Inc.). Means were compared using the LSMEANS test.Analysis of variance (ANOVA) of data presented as proportions(percentage of bulbing, dormant and flowering tillers) was carriedout after arcsin transformations. The results of categoricaltype (e.g. flowering vs. non-flowering plants, dormant vs. non-dormantplants) were analysed using contingency analysis and Pearson's ${chi}$ ²-test (Sokal and Rohlf, 1995).

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Flowering
Flowering (i.e. emergence of panicles) under LD was rare andsporadic. Pre-chilling (LT₆) resulted in 3–9 % floweringin A–F, SA–F and SA–NF ecotypes at 16/10 and22/16 °C. Without pre-chilling (LT₀), 15 % of SA–Fand SA–NF plants flowered at 16/10 °C (n = 30–33).No flowering was observed in the M–NF ecotype at all thegrowth temperatures. None of the ecotypes flowered at 28/22°C.

Under SD, in contrast, a high proportion of the plants floweredin all ecotypes, depending on the growth temperature. The ageat flowering was earlier (Fig. 1) and the percentage of floweringwas higher at 16/10 °C compared with at 22/16 °C, butnearly no flowering occurred at 28/22 °C (Fig. 2). Evenecotypes that did not flower in the net-house under outdoorconditions (SA–NF and M–NF) reached flowering inSD 16/10 °C. The ‘flowering’ ecotypes A–Fand SA–F showed earlier flowering (by approx. 30 d), particularlyat 16/10 °C and without pre-chilling (Fig. 1). The mesicecotype M–NF did not flower at 22/16 °C. These effectsof ecotype and growth temperature on flowering age were consistentand highly significant (Table 2). In contrast, the effect ofpre-chilling (LT₆) on flowering was complex, and changed withplant age (Figs 1 and 2; Tables 2 and 3). Pre-chilling delayedflowering in the ecotypes from the arid and semi-arid habitats(A–F, SA–F and SA–NF), but not in the mesic,M–NF ecotype (Fig. 1). The effects of pre-chilling onthe percentage of flowering 3 months after planting were notconsistent (Fig. 2A and B; Table 3): flowering was increasedby pre-chilling in SA–NF at 16/10 °C ( ${chi}$ ² = 11·04,P = 0·0009) and in SA–F at 22/16 °C ( ${chi}$ ² = 11·62,P = 0·0007), but was reduced in A–F at 22/16 °C( ${chi}$ ² = 6·88, P = 0·0087). Differences in percentageof flowering due to pre-chilling mostly disappeared 5 monthsafter planting (Fig. 2C and D), except for a reduction in floweringof A–F and SA–NF at 22/16 °C ( ${chi}$ ² = 8·57,P = 0·0034 and ${chi}$ ² = 12·14, P = 0·0005, respectively).In spite of these inconsistencies, pre-chilling generally postponedflowering and diminished the proportion of flowering plants.

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FIG. 1. Effects of pre-chilling and growth temperature on the age of flowering in P. bulbosa plants growing under SD (9 h). Pre-chilled bulbs (LT₆) were planted in wet substrate at 5 °C for 6 weeks; control bulbs (LT₀) were stored dry at 20–25 °C for 6 weeks. Sprouted plants from both treatments continued growth at 16/10, 22/16 and 28/22 °C (day/night). Data for 28/22 °C and for M–NF at 22/16 °C are not given due to the lack or scarcity (<13 %) of flowering. Ecotypes differed in rainfall at the site of origin and flowering capacity: plants were from an arid habitat (110 mm rain year^–1), of ‘flowering’ type (A–F); semi-arid ‘flowering’ and semi-arid ‘non-flowering’ (276 mm rain year^–1: SA–F and SA–NF, respectively) and M–NF, mesic (810 mm rain year^–1) ‘non-flowering’. SA–F and SA–NF ecotypes co-occur in the same habitat. Data are means and s.e. n = 22–30 plants. Age is presented as days from 7 d after sprouting (LT₀), or from the end of pre-chilling (LT₆), both 2·5 leaves per plant.

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FIG. 2. Effects of pre-chilling and growth temperature on the percentage of flowering plants of P. bulbosa growing at SD (9 h), at age 3 months (A and B) and 5 months (C and D), of four ecotypes differing in rainfall at the site of origin and flowering capacity: arid habitat and ‘flowering’ (A–F); semi-arid, ‘flowering’ (SA–F); semi-arid, ‘non-flowering’ (SA–NF); and mesic, ‘non-flowering’ (M–NF). SA–F and SA–NF ecotypes co-occur in the same habitat. Pre-chilled bulbs (LT₆) were planted in a wet substrate at 5 °C for 6 weeks; control bulbs (LT₀) were stored dry at 20–25 °C for 6 weeks. Sprouted plants from both pre-treatments continued growth at 16/10, 22/16 and 28/22 °C (day/night). Data are means ± s.e. n = 22–30 plants.

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TABLE 2. Statistical analyses (ANOVA) of the effects of ecotype, pre-chilling (5 vs. 20–25 °C) and growth temperature (16/10, 22/16 and 28/22 °C) on age of flowering, percentage of flowering tillers and number of panicles per plant in SD (9 h), and age of dormancy in LD (16 h)

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TABLE 3. Statistical analyses (contingency analysis and Pearson's ${chi}$ ²-test) of the effects of ecotype, pre-chilling (5 vs. 20–25 °C) and growth temperature (16/10, 22/16 and 28/22 °C) on the percentage of flowering and the percentage of dormant P. bulbosa plants in SD (9 h), at age 3 months and 5 months after planting

Differences among ecotypes in flowering response to growth temperaturewere particularly evident after 3 months of growth (Fig. 2A, B).In the ‘flowering’ ecotypes (A–F and SA–F),90–100 % of the plants flowered at 16/10 °C, comparedwith the ‘non-flowering’ ecotypes that reached 30and 75 % flowering in SA–NF and 0 and 10 % in M–NF,in the LT₀ and LT₆ pre-treatments, respectively. At 22/16 °C,flowering occurred mainly in the ‘flowering’ ecotypes.The percentage of flowering increased in all ecotypes after5 months of growth at 16/10 and 22/16 °C, but remained practicallynil at 28/22 °C (Fig. 2C, D), even in ecotypes that floweredprofusely at 16/10 °C. M–NF plants that did not flowerat 3 months reached considerable flowering under 16/10 °Cat 5 months, though at 22/16 °C they did not flower. Thus,at 16/10 °C, all ecotypes reached >75 % flowering, withand without the pre-chilling treatments (except M–NF LT₆with 50 % flowering). The effect of pre-chilling (LT₆) on thepercentage of flowering at age 5 months was negative, particularlyfor ecotypes A–F and SA–NF at 22/16 °C and M–NFat 16/10 °C.

The number of panicles per plant and the percentage of floweringtillers were additional criteria to evaluate ecotypic differencesin flowering response to temperature treatments under SD. Bothparameters were unaffected by pre-chilling (Table 2). Therefore,data from LT₀ and LT₆ treatments were pooled (Fig. 3). The effectsof ecotype and growth temperature on both parameters were highlysignificant (Table 2). Panicles per plant (Fig. 3A) and percentageof flowering tillers (Fig. 3B) were highest at 16/10 °C,decreased markedly at 22/16 °C and were almost nil at 28/22°C. ‘Flowering’ ecotypes A–F and SA–Fhad a higher percentage of flowering tillers and more paniclesper plant than ‘non-flowering’ ecotypes, particularlyat 22/16 °C where very few tillers (<2 %) flowered inthe ‘non-flowering’ ecotypes. Furthermore, bothparameters were significantly higher in SA–F than in theco-occurring SA–NF ecotype (panicles per plant, P = 0·003and P < 0·0001 for 16/10 and 22/16 °C, respectively;percentage of flowering tillers, P < 0·0001 for bothtemperatures). The M–NF ecotype had the lowest percentageof flowering tillers and panicles per plant.

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FIG. 3. Effects of growth temperature (16/10, 22/16 and 28/22 °C day/night) on the number of panicles per plant (A) and the percentage of flowering tillers (B) in four ecotypes of P. bulbosa growing at SD (9 h), age 5 months, differing in rainfall at the site of origin and flowering capacity: arid habitat and ‘flowering’ (A–F); semi-arid, ‘flowering’ (SA–F); semi-arid, ‘non-flowering’ (SA–NF); and mesic, ‘non-flowering’ (M–NF). SA–F and SA–NF ecotypes co-occur in the same habitat. Data of pre-chilled and non-pre-chilled (control) treatments were pooled, since differences between the two pre-treatments were not significant. Data are means ± s.e. n = 30 plants.

Dormancy
Under LD, plants became dormant much earlier than under SD,as shown by the percentage of dormant plants at age 3 months(Fig. 4A, B, and C, D). Moreover, while LD plants of all ecotypesand temperature treatments became dormant between age 1 and4 months (Fig. 5), most SD plants from all ecotypes were stillgrowing actively at the end of the experiment (age 5 months)at 16/10 and 22/16 °C (Fig. 4E, F). LD plants became dormantearlier the higher the growth temperature and after pre-chilling,compared with unchilled plants. These effects were highly significant(Fig. 5, Table 2). The enhancing effect of pre-chilling wassignificant only in the ‘non-flowering’ ecotypes,that entered dormancy late (SA–NF and M–NF; P =0·001), while in the ‘flowering’ ecotypes(A–F and SA–F), the pre-chilling effect on dormancyimposition was not significant (P = 0·57 and 0·06,for A–F and SA–F, respectively).

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FIG. 4. Effects of pre-chilling and growth temperature on the percentage of dormant P. bulbosa plants at age 3 months, under LD (A and B) and SD (C and D), and at age 5 months of SD plants (E and F), in ecotypes differing in rainfall at the site of origin and flowering capacity: arid habitat and ‘flowering’ (A–F); semi-arid and ‘flowering’ (SA–F); semi-arid, ‘non-flowering’ (SA–NF); and mesic, ‘non-flowering’ (M–NF). SA–F and SA–NF ecotypes co-occur in the same habitat. Pre-chilled (LT₆) bulbs were planted in wet substrate at 5 °C for 6 weeks; control bulbs (LT₀) were stored dry at 20–25 °C for 6 weeks. Sprouted plants from both pre-treatments continued growth at 16/10, 22/16 and 28/22 °C (day/night). Data are means ± s.e. n = 22–30 plants.

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FIG. 5. Effects of pre-chilling and growth temperature on age at dormancy of P. bulbosa at LD (16 h), in ecotypes differing in rainfall at the site of origin and flowering capacity: arid habitat and ‘flowering’ (A–F); semi-arid, ‘flowering’ (SA–F); semi-arid, ‘non-flowering’ (SA–NF); and mesic, ‘non-flowering’ (M–NF). SA–F and SA–NF ecotypes co-occur in the same habitat. Pre-chilled bulbs (LT₆) were planted in wet substrate at 5 °C for 6 weeks; control bulbs (LT₀) were stored dry at 20–25 °C for 6 weeks. Sprouted plants from both pre-treatments continued growth at 16/10, 22/16 and 28/22 °C (day/night). Data are means ± s.e. n = 27–33 plants. Age is presented as days from 7 d after sprouting (LT₀), or from the end of pre-chilling (LT₆), both 2·5 leaves per plant.

Under SD, dormancy imposition recorded at age 3 and 5 monthswas also greatly enhanced by increasing growth temperature andby pre-chilling (Table 3; Fig. 4C–F). At 16/10 °C,no or few dormant plants (<25 %) were observed in all ecotypes,even after 5 months of growth, while at 28/22 °C the proportionof dormant plants was high. Dormancy promotion by pre-chilling(Table 3) was clearly seen at 22/16 and 28/22 °C. At 22/16°C, all ecotypes were non-dormant in the LT₀ treatment atage 3 months, compared with 30–50 % in the A–F,SA–F and SA–NF ecotypes in the LT₆ treatment.

Ecotypes differed in patterns of dormancy response under bothLD and SD. Under LD, ecotypes whose parent plants flowered inthe net-house (A–F and SA–F) became dormant earlierthan those from ‘non-flowering’ ecotypes (SA–NFand M–NF) (Fig. 5; Table 2). The differences between A–Fand SA–F vs. M–NF ecotypes were highly significant(P < 0·0001) in all growth temperature and pre-chillingcombination treatments. Moreover, plants of the ‘flowering’SA–F ecotype became dormant earlier than plants of the‘non-flowering’ SA–NF, even though they co-occurin the same site. The M–NF ecotype became dormant considerablylater than the SA–NF in five out of the six growth temperature–pre-chillingcombinations (P < 0·001). The enhancing effect ofincreasing growth temperature on earliness of dormancy onsetwas similar in the four ecotypes, as shown by the weak, thoughsignificant, temperature x ecotype interaction (Table 2).

Similar but less well defined ecotypic trends in patterns ofdormancy imposition were found in SD. At 28/22 °C, the highestpercentage of dormancy at age 3 months occurred in the SA–Fecotype (80–90 %). In A–F and SA–NF, the percentageof dormant plants was intermediate (20–40 and 40–50% in the LT₀ and LT₆, respectively;Fig. 4A, B). The M–NFecotype remained non-dormant at 16/10 and 22/16 °C and onlyapprox. 15 % dormancy was reached at 28/22 °C, even after5 months of growth (Fig. 4).

The time course for dormancy imposition was followed under LD.Earlier onset of dormancy was negatively correlated with a higherrate of dormancy imposition in both LT₀ (y = 4·70 –0·027x; r = 0·749) and LT₆ (y = 5·18 –0·037x; r = 0·760) pre-treatments (d.f. = 10,P = 0·01, in both control and pre-chilled plants). Thedifference between the two regressions was not significant.

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Flowering and dormancy in P. bulbosa were affected in oppositeways by daylength and growth temperature. Flowering was rareunder LD, but readily occurred after 3 months of growth in SDand was enhanced by low temperature (Figs 1 and 2). Dormancy,in contrast, was induced by LD and postponed by low growth temperature(Figs 4 and 5), as previously reported (Ofir and Kerem, 1982;Ofir and Dorenfeld, 1992; Ofir and Kigel, 1999). Plants alsobecame dormant under SD, but at a much later stage and mostlyunder high temperature (Fig. 4). Thus, high growth temperatureinhibited flowering under SD (Fig. 2) and enhanced dormancyunder both LD and SD (Figs 4 and 5). Furthermore, exposure ofplants to low temperature pre-treatment (6 weeks at 5 °C)accelerated dormancy imposition in LD (Figs 4A, B, and 5; Ofirand Kigel, 1999) and in some ecotypes also in SD (Fig. 4C–F),but lacked consistent effects on flowering (Figs 1 and 2).

Similar trends of earlier flowering in short days, minor orno effect of vernalization and a delay of flowering (i.e. moreleaves to flowering) due to increasing growth temperature havebeen reported for high latitude and alpine populations of perennialtypes of P. annua (Heide, 2001) and for perennial P. annua ‘reptans’populations (Johnson and White, 1997a, b). However, in contrastto P. bulbosa that did not reach flowering in long days, perennialtypes of P. annua flowered in long days at a later plant agecompared with short days, particularly under relatively lowgrowth temperatures, or after vernalization treatments (Heide,2001). In P. bulbosa, long days induced early dormancy and onlya few plants ‘escaped’ dormancy and reached floweringat low growth temperatures. The fact that flowering mostly occurredin short days, together with the lack of clear response to vernalization,suggests that in regard to flowering, P. bulbosa is a shortday plant.

It may also be argued that P. bulbosa is a facultative longday plant like most Festucoid grasses, but the early transitionto the dormant state under LD arrests reproductive developmentprematurely, before any morphological changes at the shoot apexhave occurred. Moreover, even if a shift from short day to longday is required for flowering, as in other temperate grasses(Heide, 1994), in P. bulbosa this shift will enhance the inductionof dormancy (Ofir and Kigel, 1999), thus strengthening the inhibitionof flowering under these conditions. Suppression of floweringdue to dormancy enhancement by the same environmental factorsrequired for flowering induction and inflorescence developmenthas probably also occurred in garlic (A. sativum) and onion(A. cepa), due to selection since historical times for increasedstorage in the bulbs and for earliness of maturation (Brewster,1990; Etoh and Simon, 2002). In some bolting types of garlic,the transition of the shoot apex to the reproductive state canoccur under both short and long days. However, under short days,the inflorescence fails to elongate, while under long days thefate of the inflorescence depends on the strength of long dayinduction. Increasing the number of long days leads from normalelongation and flowering to development of dormant vegetativebulbils, instead of flowers (Kamenetsky et al., 2004). Similarly,in the short day C₄ perennial grass Bouteloua eriopoda, continuedexposure to inductive short days leads to early abortion ofthe inflorescence (Schwartz and Koller, 1975). This responseis probably related to the fact that in this species the restperiod occurs during the dry winter. Altogether, it can be arguedthat natural or artificial selection for increased responsivenessto environmental factors inducing flowering could result inthe loss of flowering capacity that is associated with morphologicaland physiological processes leading to dormancy. Moreover, sincesimilar environmental factors induce summer dormancy in P. bulbosaas well as flowering in many other Festucoid grasses (i.e. longday, pre-exposure to short day or to low temperature), it isconceivable that the control of these phenological transitionscan be channelled through inter-related developmental pathways.Thus, the inhibition of flowering in P. bulbosa by high temperaturecan be attributed to enhanced responsiveness to induction ofdormancy by long days or to direct inhibition of flowering (Heide,1994).

It is noteworthy that flowering does not depend on vernalizationbut is promoted by short days in perennial types of Poa fromcontrasting habitats, such as alpine and high latitude populationsof P. annua that grow during the summer (Heide, 2001), as wellas in Mediterranean populations of P. bulbosa that grow in thewinter season. Despite the large climatic differences, bothhabitats are characterized by a relatively short growth season.In the Mediterranean and adjoining arid phytogeographic regions,P. bulbosa grows on shallow soils with a low moisture-holdingcapacity, imposing a short growth period in the winter thatis followed by a long dry summer. These were probably factorsin the evolution of the ability to achieve flowering in shortdays at low temperatures, together with the early transitionto the dormant state.

Flowering of P. bulbosa ecotypes along the steep rainfall gradientoccurs during late winter and early spring, when the daylengthranges between 11 and 12 h. This range is also the thresholddaylength for dormancy induction (Ofir and Kigel, 1999). Sincethe rainfall gradient along which the ecotypes were collectedspans a narrow latitude range, it may be assumed that the ecotypesin the field are exposed to the same daylength and quite similartemperatures along the gradient. Thus, the ecotypic variationin the capacity and timing of flowering with increasing ariditycan be interpreted as the result of balanced opposite effectsof daylength and temperature on the flowering and dormancy processes.

In the non-flowering mesic and semi-arid ecotypes, floweringdid not occur during 3 years in outdoor conditions in a net-house(Table 1), but they flowered in the phytotron under SD at thelower temperatures (M–NF at 16/10 °C; SA–NFat 16/10 and 22/16 °C, Fig. 2). Thus, lack of floweringin the field doees not necessarily indicate a loss of floweringcapacity. These non-flowering ecotypes probably have an increasedresponsiveness to the inhibitory effect of higher temperatureon flowering. It is conceivable that in the field, these ecotypescould reach flowering in years with early onset of the rainyseason and relatively cold and prolonged winters. Thus, theymay produce seeds or inflorescence bulbils only in particularlyfavourable years, relying on tiller bulbs for reproduction inthe less favourable years. In this case, the balance betweenlocal reproduction and persistency by basal bulbs vs. dispersibleseeds or bulbils produced by inflorescences is determined bythe responsiveness of the ecotype to the relevant environmentalconditions and the frequency with which these conditions occur.The facts that arid and semi-arid ecotypes (A–F and SA–F)flowered every year (Table 1), had a larger proportion of floweringplants than the mesic ecotype (M–NF) even at the intermediatetemperature (i.e. 22/16 °C) and also underwent earlier flowering(Figs 1 and 2) support the idea that a higher level of dispersalby sexual and/or asexual propagules (i.e. seeds and bulbils)has an advantage for P. bulbosa populations under arid conditions(Ofir and Kigel, 2003). At the same time, higher responsivenessof these populations to long day and high temperature inductionof dormancy reduces the risk of death due to early drought.

We conclude that the variation in the flowering capacity ofP. bulbosa ecotypes differing in drought tolerance can be seenas the result of balanced opposite effects of daylength andtemperature on the flowering and dormancy processes, thus regulatingreproductive capacity, the balance between seed and vegetativereproduction and adaptation to prolonged drought during thesummer.

LITERATURE CITED

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

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