Influence of simulated snow cover on the cold tolerance and freezing injury of yellow-cedar seedlings

It has been hypothesized that yellow‐cedar [Chamaecyparis nootkatensis (D. Don) Spach] decline may result from root freezing injury following climate change‐induced reductions in protective snow cover. To test this hypothesis, we measured the freezing tolerance and injury expression of yellow‐cedar seedlings in three treatments that differed in the insulative protection they provided to soils during winter and spring: (1) full exposure to ambient temperatures (exposed treatment), (2) continuous protection from ambient temperatures via addition of perlite over pots (full protection), and (3) perlite protection only during winter and exposure to ambient temperatures during spring (partial protection). Foliage from all treatments was cold tolerant enough to prevent foliar freezing injury throughout the study period. However, on all sample dates, roots of seedlings from all treatments were only tolerant to about ?5 °C – a level considerably warmer than the reported maximum cold tolerance for the species and well above the soil temperature recorded in the exposed treatment. As a result of this limited root cold tolerance, visibly uninjured roots of seedlings from the exposed treatment had significantly higher relative electrolyte leakage (REL) throughout the winter and early spring than seedlings in soil protection treatments. Seedlings from the exposed treatment also had significantly higher foliar REL values and greater visual foliar injury than seedlings from the other treatments starting in early spring. For both roots and foliage, REL measurements consistently detected tissue damage before visual injury was evident. Patterns of injury from both REL and visual injury assessments showed the same pattern: damage began with freezing injury to roots and subsequently became evident as foliar browning after spring temperatures increased. All seedlings in the exposed treatment eventually had 100% fine root damage and died. This progression of initial root damage followed by foliar browning and mortality after the onset of warming conditions is consistent with reports of yellow‐cedar decline symptom development in the field.     

Influence of soil temperature on root freezing tolerance of Scots pine (Pinus sylvestris L.) seedlings

The influence of soil temperature on the root freezing tolerance of one-year-old containerized Scots pine (Pinus sylvestris L.) seedlings was investigated. In addition, the TTC and electrolyte leakage methods were evaluated in terms of their suitability for use in detecting damage to roots caused by freezing. In mid-August, seedlings were placed in three thermostat-controlled soil beds in a greenhouse with an initial soil temperature of 14.3 °C. Soil temperature was lowered in two of the soil beds, resulting in temperatures of 10.7 and 5.3 °C respectively. Each soil temperature, i.e. 14.3, 10.7 and 5.3 °C was maintained for eight weeks. Starting in early September, damage to roots induced by artificial freezing was estimated biweekly by measuring electrolyte leakage, triphenyl tetrazolium chloride (TTC) reduction and potential root growth in a three-week cultivation test. In addition, the root freezing tolerance of seedlings placed outdoors was tested. Measurements showed that these seedlings were exposed to soil temperatures ranging from 13.0 °C in mid-August to 0.5 °C in November. Generally, the development of root freezing tolerance was more pronounced for seedlings exposed to lower (0.5 and 5.3 °C) soil temperatures compared with those exposed to higher (10.7 and 14.3 °C) ones. Root freezing tolerance was highest among the seedlings placed outdoors which were also exposed to the lowest soil temperatures registered in the study. To examine the effect of a temporary warm period, the soil temperature in one treatment was increased from 5.4 °C to 13.9 °C, maintained at the latter temperature for two weeks in October and then lowered to 5.7 °C. Root freezing tolerance was reduced by exposure to the warmer soil temperature. However, after four weeks at the colder soil temperature, the tolerance of the seedlings had returned to the level measured prior to exposure to the warm soil temperature. Methods based on the measurement of root electrolyte leakage and TTC reduction were both found to have limitations when used to detect root freezing damages in containerized seedlings. This revised version was published online in June 2006 with corrections to the Cover Date.     

The effect of soil freezing on the survial of winter-sown white lupins (Lupinus albus L.)

Specially constructed soil-freezing growth boxes were used to study the effects of the intensity and duration of soil freezing on root injury and the survival of white lupin seedlings of different ages under controlled conditions. The extent of root damage depended on both the intensity of soil freezing and the stage of seedling development (measured as the extent of lignification of the central stele of the primary root). Seedlings whose secondary root development was well advanced, and in which the endodermis was completely lignified, survived intense soil freezing intact. Young seedlings with weakly lignified roots were damaged by moderate soil freezing (> 5 days at ?1°C) and killed by more intense freezing (5 days at ?2°C). The extent of root development and ligmfkation was correlated with the number of leaf primordia produced at the shoot apex so that the susceptibility to soil freezing damage could be accurately predicted by a simple physiological/leaf production model.     

The electrolyte leakage method can be misleading for assessing the frost hardiness of roots

Abstract

The relative electrolyte leakage (REL) method is often used to assess the frost hardiness of plant organs. However, testing the frost hardiness of roots with REL yields different results when the roots are frozen while remaining in the soil or in some other substrate than when REL follows a freezing test made on excised root segments. In this study, we show that the electrolytes may already leak out of injured roots during freeze/thaw treatment and during washing of the roots after the treatment. In this case, the conductivities measured after the freezing test and killing of the tissue both give lower readings than expected for injured samples, and hence the results of the REL are incorrect. We suggest that roots should be washed free of soil and placed in test tubes prior to the freezing test. The leakage of electrolytes from injured roots to soil may also limit the use of the REL method for measuring root viability.     

Combined drought and episodic freezing effects on seedlings of low- and high-elevation subspecies of sagebrush (Artemisia tridentata)

Big sagebrush ( Artemisia tridentata ) is a dominant shrub throughout much of the arid western United States. Several recognized subspecies differ in physiology, morphology and in their distribution in relation to soil water availability. While several studies have compared mature individuals of these subspecies, there is little information on seedling physiological tolerance to physical stresses. Understanding seedling physiology is essential for predicting how species may respond to changes in temperature and precipitation regimes. Our objective was to examine the drought and freezing tolerance of seedlings of two A. tridentata subspecies: ssp. tridentata , which is found in low-elevation dry sites, and ssp. vaseyana , found in higher, moister sites. We examined growth, gas exchange and quantum yield of chlorophyll a fluorescence from photosystem II (PSII) for seedlings grown in a greenhouse and exposed to two different levels of moisture availability in combination with a simulated growing season freezing event. We found that ssp. tridentata possessed several drought-tolerant characteristics, such as rapid growth rates, thick leaves and low stomatal conductance. Both subspecies shared similar physiological tolerance to the low-moisture treatment but experienced relatively more stress under the freezing treatment. Subspecies vaseyana was more sensitive to freezing when grown with low soil moisture, resulting in reduced stomatal conductance and PSII quantum yield. In contrast, the low-soil moisture treatment did not increase the susceptibility of ssp. tridentata to freezing. These results demonstrate that drought tolerance may be an important trait for seedlings of A. tridentata , but stress because of freezing damage of seedlings may limit the distribution of the species.     

Effect of a strong cold storage induced desiccation on metabolic solutes,stock quality and regrowth,in seedlings of two oak species

Bare-root seedlings of pedunculate oak (Quercus robur L.) and northern red oak (Quercus rubra L.) were lifted in January and stored at 1.8°C, at 82% relative humidity, until their fresh weight declined by 33%. Root growth potential (RGP), fine root electrolyte leakage (REL), fine root water content (RWC), shoot tip water content (SWC), starch and metabolic solute contents in root and shoot, were measured just after lifting and after treatment. Survival of treated seedlings was also assessed in a field trial. RWC, SWC, REL, RGP were dramatically affected by desiccation during cold storage. In both species, root soluble carbohydrate level, inositol level and isocitrate level increased, whereas root starch level and shoot soluble carbohydrate level decreased. In northern red oak, treated seedlings had higher root contents of soluble carbohydrates, inositol and proline than in pedunculate oak. Moreover, treatment induced proline accumulation only in northern red oak roots. These differences could explain why field survival of treated seedlings was significantly better in northern red oak than in pedunculate oak.     

Genome-wide association study for electrolyte leakage in rapeseed/canola (<Emphasis Type="Italic">Brassica napus</Emphasis> L.)

Freezing temperature/frosts can cause significant damage to plants by rupturing plant cells. Rapeseed/canola (Brassica napus L.) is susceptible to freezing temperature at early seedling stage. The degree of cell rupture or seedling damage can be evaluated through the measurement of electrolyte leakage. Here, we measured the electrolyte leakage of a diversity panel of B. napus germplasm accessions under simulated freezing conditions. Preliminary data for electrolyte leakage measurement indicated that cold acclimation of two-week-old seedlings for 7 days at 4 °C followed by freezing treatment at ??12 °C for 2 h provided a reasonable diversity in response. With this protocol for electrolyte leakage, a genome-wide association study was conducted on 157 winter, semi-winter, and spring types of B. napus accessions that originated from 17 countries. A total of 37,454 single-nucleotide polymorphism (SNP) markers based upon genotyping-by-sequencing were used for the analysis. Ten QTL were identified as associated with electrolyte leakage of canola seedlings, which together explained 43% phenotypic variation. Five of the QTL were located on A-genome. We identified at least 33 orthologs of the functional candidate genes. Although no well-characterized cold regulatory genes were identified, there were some indications that genes involved in membrane structure, developmental processes, and extracellular transport may be involved in altering the electrolyte leakage following the short-term hard freeze and rapid defrosting suffered by the plants in our protocol.     

Abscisic Acid induces anaerobiosis tolerance in corn

Flooding is a frequently occurring environmental stress that can severely affect plant growth. This study shows that treatment of corn (Zea mays L.) seedlings with abscisic acid (ABA) increases their tolerance to anoxia 10-fold over untreated seedlings and twofold over seedlings treated with water. Corn seedlings stressed anoxically for 1 day showed only 8% survival when planted in vermiculite. Pretreatment of root tips with 100 micromolar ABA or water for 24 hours before the 1 day anoxic stress increased the anoxic survivability of seedlings to 87% and 47%, respectively. Cycloheximide (5 milligrams per liter), added together with ABA, reduced the seedling survival rate, indicating that the induction of anoxic tolerance in corn by ABA was partly a result of the synthesis of new proteins. ABA treatment induced a threefold increase in alcohol dehydrogenase enzyme activity in corn roots. However, after 24 h of anoxia, alcohol dehydrogenase enzyme activity between the ABA-pretreated and non-pretreated corn roots was not significantly different. The results indicated that ABA played an important role in inducing anoxic tolerance in corn and that the induced tolerance was probably mediated by an increase in alcohol dehydrogenase enzyme activity before the anoxic stress.     

Uniconazole-induced thermotolerance in soybean seedling root tissue

Soybean [Glycine max(L.) Merr. cv. A2] seeds were germinated in 0 or 1 mg 1¹ (3.4 uM) uniconazole, after which seedling roots were excised and exposed to 22 or 48°C for 90 min. Prior to the temperature treatments there were few ultrastructural differences between uniconazole-treated seedling roots and the controls. Following exposure to 48°C, electron micrographs revealed near complete loss of normal ultrastructure in control epidermal root cells, whereas cellular integrity was maintained in treated roots, indicating that uniconazole conferred tolerance to high temperature. Total electrolyte, sugar and K⁺ leakage were all greater from control roots than treated roots during exposure to 48°C. Proline content in the roots was unaffected by uniconazole at 22°C but was 25–30% greater in treated tissue than in controls following exposure to 48°C. Malondialdehyde content was unaffected by uniconazole at 22°C but was nearly 20% less in treated tissue than in controls following high temperature exposure. This indicates that uniconazole decreased high-temperature-induced lipid peroxidation. Uniconazole elevated several antiox-idant systems in the roots, including water-soluble sulfhydryl concentration and catalase, peroxidase and superoxide dismutase activities. These findings are consistent with the hypothesis that uniconazole-induced stress tolerance is due, at least in part, to enhanced antioxidant activity which reduces stress-related oxidative damage to cell membranes.     

嫁接对铜胁迫下黄瓜幼苗根系多胺代谢的影响

采用营养液栽培法,研究了嫁接(以黑籽南瓜为砧木)对铜胁迫下黄瓜幼苗根系活力及多胺代谢的影响.结果表明:铜胁迫下黄瓜幼苗根系活力下降,电解质渗漏率升高,而嫁接苗的变化幅度显著小于黄瓜自根苗;铜胁迫下黄瓜嫁接植株根系中除游离态腐胺(Put)含量显著低于自根苗外,结合态和束缚态Put、3种形态亚精胺(Spd)和精胺(Spm)含量均显著高于自根苗,嫁接苗根系中游离态Put含量及腐胺/多胺(Put/PAs)显著低于自根苗;铜胁迫下,嫁接苗根系精氨酸脱羧酶(ADC)、鸟氨酸脱羧酶(ODC)和S-腺苷蛋氨酸脱羧酶(SAMDC)活性高于自根苗,而二胺氧化酶(DAO)和多胺氧化酶(PAO)活性显著低于自根苗.表明嫁接黄瓜幼苗根系PAs的合成增加,降解减少,使PAs含量维持在较高水平,从而提高了黄瓜幼苗抗铜胁迫能力.     

盐胁迫对盐生植物黄花补血草种子萌发和幼苗生长的影响

盐生植物黄花补血草广泛分布于我国西北地区、东北西部以及华北北部,对改良盐碱土壤具有重要的生态作用。以黄花补血草(Limonium aureum(L.)Hill)为材料,研究分析了不同浓度NaCl胁迫对其种子萌发和幼苗生长产生的抑制效应及作用机制。结果表明:低浓度NaCl(25 mmol/L和50 mmol/L)处理不影响黄花补血草种子萌发和幼苗生长,25 mmol/L NaCl甚至促进了根生长,而高浓度NaCl(100 mmol/L和150 mmol/L)处理明显抑制种子萌发及幼苗生长。利用荧光探针的检测结果表明,NaCl处理的幼苗根中过氧化氢(H2O2)和一氧化氮(NO)含量明显高于对照水平。碘化丙啶(PI)染色结合激光共聚焦显微镜观察及检测相对电导率结果显示,高浓度NaCl处理抑制了幼苗根尖伸长区细胞的伸长生长,增加了细胞膜的通透性,对根细胞造成了明显的伤害。此外,高浓度NaCl处理诱导叶片丙二醛(MDA)含量显著升高。以上结果说明,黄花补血草对低浓度的盐具有一定的耐盐性,但高浓度盐降低了种子的萌发率,使幼苗根中H2O2产生增加,抑制根尖伸长区细胞的伸长生长,对根、叶造成明显氧化损伤,从而抑制黄花补血草幼苗的生长。     

The roles of seedling salt tolerance and resprouting in forest zonation on thewest coast of Florida, USA

To determine whether the zonation of seven coastal tree species in north Florida correlated with the relative abilities of their seedlings to tolerate soil salinity, we subjected seedlings of Sabal palmetto, Juniperus virginiana var. silicicola, Quercus virginiana, Celtis laevigata, Ulmus spp., Acer floridanum, and Liquidambar styraciflua to a range of salinities (～0, 2, 4, 8, 15, and 22 g synthetic sea salt/L; up to 63% full strength seawater salinity) in a 6-mo greenhouse experiment. Pots with shoot-killed plants were flushed with freshwater for ≥5 wk to assess recovery. Salt tolerance was assessed as plant survival under saline conditions and as the ability to retain green leaf tissue under saline conditions. Using either criterion, the rank order of seedling salt tolerance correlated significantly (P ≤ 0.05) with that expected based on species zonation near the coast. Agreement was better, however, using retention of leaf tissue as an index of salt tolerance. Species from forest zones that were frequently exposed to tidal water retained green leaf tissue under saline conditions. Species from zones occasionally subjected to very high tides were shoot killed but resprouted following removal of salt from the root zone. Those restricted to zones exposed only to infrequent storm surges died at salinities ≥4 g/L. Thus, differential seedling salt tolerance was consistent with tree zonation and, although the ability of young seedlings to resprout following salt removal did not appear to allow tree establishment at the extreme seaward margin of the forest, it appeared important in intermediate zones.     

Ecophysiological adaptations of black spruce (<Emphasis Type="Italic"> Picea mariana</Emphasis>) and tamarack (<Emphasis Type="Italic"> Larix laricina</Emphasis>) seedlings to flooding

Black spruce [ Picea mariana (Mill.) B.S.P.] and tamarack [ Larix laricina (Du Roi) K. Koch] are the predominant tree species in boreal peatlands. The effects of 34 days of flooding on morphological and physiological responses were investigated in the greenhouse for black spruce and tamarack seedlings in their second growing season (18 months old). Flooding resulted in reduced root hydraulic conductance, net assimilation rate and stomatal conductance and increased needle electrolyte leakage in both species. Flooded tamarack seedlings maintained a higher net assimilation rate and stomatal conductance compared to flooded black spruce. Flooded tamarack seedlings were also able to maintain higher root hydraulic conductance compared to flooded black spruce seedlings at a comparable time period of flooding. Root respiration declined in both species under flooding. Sugar concentration increased in shoots while decreasing in roots in both species under flooding. Needles of flooded black spruce appeared necrotic and electrolyte leakage increased over time with flooding and remained significantly higher than in flooded tamarack seedlings. No visible damage symptoms were observed in flooded tamarack seedlings. Flooded tamarack seedlings developed adventitious roots beginning 16 days after the start of flooding treatment. Adventitious roots exhibited significantly higher root hydraulic conductivity than similarly sized flooded tamarack roots. Flooded black spruce lacked any such morphological adaptation. These results suggest that tamarack is better able to adjust both morphologically and physiologically to prolonged soil flooding than black spruce seedlings.     

Farinose freezing （Primula flavonoids,are associated with high tolerance in fairy primrose malacoides） plants

The deposition of surface （farinose） flavonoids on aerial parts of some Primula species is a well-documented but poorly understood phenomenon. Here, we show that flavonoid deposition on the leaves and winter buds may contribute strongly to preventing freezing damage in these plants. The ice nucleation temperature of fairy primrose （Primula malacoides） leaves covered with natural flavone was approximately 6~C lower compared to those that had their flavone artificially removed. Additionally, farinose flavonoids on the leaves reduced subse- quent electrolyte leakage （EL） from the cells exposed to freezing temperatures. Interestingly, exogenous application of flavone at 4 mg/g fresh weight to P. malacoides leaves, which had the original flavone mechanically removed, restored freezing tolerance, and diminished EL from the cells to pretreatment values. Our results suggest that farinose flavonoids may function as mediators of freezing tolerance in P. malacoides, and exogenous application of flavone could be used to reduce freezing damage during sudden but predictable frost events in other plant species.     

小麦幼苗根系形态与反复干旱存活率的关系

以35个不同栽培类型的小麦品种（系）作为试验材料,根据其6叶幼苗的根系形态性状进行聚类分析,供试材料的根系类型分为3种：大根系、小根系和中间型根系。具有中间型根系的材料反复干旱存活率最高,这些材料的根系特点是单株根数7－8．5条,最大根长20-22cm,根总干重44－48mg,其中10cm以下根干重占36％－45％,根冠比范围在0.22-0.24。一些水地栽培的育成品种苗期抗旱性较强,旱地栽培的育成品种苗期抗旱性差异较大,个别旱地栽培的地方品种在土壤水分胁迫条件下反而比在正常水分条件下的根系发育更好,可能是长期适用干旱条件的结果。     

Improving vigour assessment of pine (Pinus nigra Arnold) seedlings before their use in reforestation

ABSTRACT

We investigated whether changes in the root system of pine seedlings induced by stress (lifting of bare-root seedlings from the nursery bed irrespective of dormancy; prolonged storage of bare-root seedlings in a cold room) could provide a measure of plant vigour. Physiological parameters, such as growth potential and root electrolyte leakage, and morphological parameters, such as root length and number of root tips, were calculated. Computerised image analysis was used to measure root growth, overall and based on root-diameter class (0–0.5 mm, 0.5–1.0 mm and 1.0–1.5 mm). The efficiency of vigour assessment was evaluated by correlating the data for each parameter with percentage seedling survival. Root growth potential was more efficient than root electrolyte leakage, but both parameters were affected by seedling age. Total root length was a more efficient indicator of plant vigour than root tip number, particularly when referred to roots of the same diameter class. A comparative analysis of physiological and morphological parameters referred to the root systems improves their relative effciency.     

Involvement of polyamines in the interacting effects of low temperature and mineral supply on Pringlea antiscorbutica (Kerguelen cabbage) seedlings

Pringlea antiscorbutica, which is the sole endemic crucifer in the subantarctic zone, undergoes seedling development in a harsh and cold environment. Since, at the mature stage, this species exhibits several adaptations linked to cold tolerance such as high polyamine levels, potential adaptations and polyamine response were investigated in seedlings. In order to assess the specificity of responses, P. antiscorbutica was compared with Arabidopsis thaliana, which is characterized by a life cycle preventing cold exposure at seedling stage. P. antiscorbutica and A. thaliana seedlings were found to have strikingly contrasted responses to temperature changes and to mineral nutrition. Whereas A. thaliana seedlings showed the typical growth arrest of chilling-sensitive plants, P. antiscorbutica seedlings showed optimal root growth at low temperature (5/10 degrees C) and temperate conditions caused the early arrest of root growth. Cold tolerance was associated with increased levels of polyamines or with maintenance of high levels of polyamines. Comparison of both species showed that polyamine levels could be a significant marker of chilling tolerance in seedlings. Treatments with varying mineral supply showed a positive relationship between root growth rate and variations of agmatine and putrescine endogenous contents in roots of P. antiscorbutica. This may be the first demonstration that, even under conditions of accumulation induced by environmental stress, polyamine levels can still be correlated with developmental processes. Com parison of mineral supply and temperature effects strongly indicated a trade-off of polyamine involvement between development and response to stress.     

Chilling Sensitivity of Photosynthetic Oil-Seedlings

Seed germination and seedling emergence are particularly sensitiveto low temperatures in oil-seed genera in which lipids are themain seed storage material, e g cotton, corn, cucumber, andwatermelon Growth of photosynthetic seedlings of oil-seed generais also significantly affected by suboptimal temperatures. Aphotosynthetic seedling growth system used to demonstrate suboptimaltemperature stress effects in cotton was modified to monitorthe effects of temperatures from 10 to 35 ? upon the roots andaerial portions of cucumber, cantaloupe, and watermelon seedlings.Non-destructive measurements of fresh weights and the relativewater contents of the roots and shoots of seedlings grown at30 ? and at non-optimal temperatures, as well as chilled seedlingsreturned to 30 ? for one day, indicated significant intra-genencdifferences in temperature sensitivity and relative root andshoot water status of both the chilled seedlings and those recoveringfrom thermal stress The capacity to return to normal water statusand resume growth differed between and within species and wascorrelated with recommendations for chilling tolerance Key words: Temperature, water stress, photosynthetic seedling     

Effects of gravitropic stress on the development of the primary root of lentil seedlings grown in space

Root growth and cell differentiation were analysed in lentil seedlings grown (1) in microgravity (F microg), (2) on the 1 x g centrifuge (F1 x g), (3) in microgravity and placed on the 1 x g centrifuge for 4 h [F(microg + 1 x g)], (4) on the 1 x g centrifuge and placed in microgravity for 4 h [F(1 x g + microg)]. In microgravity, there were strong oscillations of the root tip, even when the seedlings were grown first on the 1 x g centrifuge [F(1 x g + microg)]. In the [F(microg + 1 x g)] sample, the roots grown in microgravity were oblique with respect to the 1 x g acceleration when the seedlings were placed on the centrifuge. They were therefore gravistimulated. However, root length was similar in the 4 samples after 29 h of growth and growth rate of the root was the same between 25 h and 29 h although it appeared to be slightly greater in the [F(microg + 1 x g)] sample. Cell elongation was analysed as a function of the distance from the root cap junction. Cell length was similar in the seedlings grown in microgravity or on the 1 x g centrifuge. The transfer from the 1 x g centrifuge to microgravity [F(1 x g + microg)] did not modify cell elongation in the roots. Cell length in the roots which were grown in microgravity and gravistimulated [F(microg + 1 x g)] was different from that observed in microgravity but this was only due to gravistimulation. Thus, gravity does not have an effect on cell elongation when the roots are strictly oriented in the vertical position but it does as soon as the root tip deviates from this orientation.     

Rapid root extension during water pulses enhances establishment of shrub seedlings in the Atacama Desert

Questions: (1) What is the water threshold for shrub seedling establishment in arid scrubland? (2) How do seedling root growth morphological traits affect the water threshold required for seedling establishment? Location: Arid scrubland, Atacama Desert, north‐central Chile. Methods: We conducted a field experiment with nine native shrub species under a gradient of simulated rainfall to test if species with deep root architecture have higher seedling survival rates and establish more successfully during water pulses. Results: Seedling survival rate was very low; only 2% of the 12 150 planted seedlings survived the first summer drought. Seedling survival required at least 206 mm of water, which is twice the average rainfall and roughly equivalent to the precipitation during an ENSO (El Niño Southern Oscillation) event in this region. Seedling survival at the onset of the summer drought was best explained by leaf habit, root length and initial seedling size. However, only Senna cumingii seedlings survived through the first year. S. cumingii seedlings had distinctively longer roots than the other shrub species, enabling them to reach moister soil layers. Conclusions: Water conditions resembling rainy years enhance shrub seedling establishment in the Atacama Desert, but the effects of higher water availability are strongly dependent on the shrub species. Rapid and deep rooting appears to be a very important functional trait for successful first‐year survival in this arid system where water availability is highly episodic.