Comparative Physiological and Molecular Analyses of Intraspecific Differences of Stipa purpurea (Poaceae) Response to Drought

Stipa purpurea Griseb, the dominant species of alpine steppe, is widely distributed across the large precipitation gradient on the Tibetan Plateau. It is possible that because of local adaptation, Spurpurea populations from different habitats along this precipitation gradient respond differently to drought, which may affect their responses to climate change. To explore the problem, in the present study, we investigated the physiological and molecular response of Spurpurea seedlings from two different populations (Pulan & Cuoqin) to 14 d drought stress and subsequent recovery. The results showed that the relative water content, chlorophyll fluorescence, content of osmoticant proline and malondialdehyde (indicator of oxidative stress), accumulation of reactive oxygen species, antioxidant enzyme activities and the expression of drought related genes all changed under drought treatment and went back to the control levels in the subsequent recovery in plants from Pulan. However, these patterns were quite different in plants from Cuoqin, in which these traits changed by inconsistent degrees and did not return to pretreatment levels after rewatering. The results demonstrated that the plants from Pulan had greater resistance to drought stress compared with those from Cuoqin, which had a larger mortality rate ultimately. Combating the differences of offspring in response to drought and the habitat distribution of parents, we considered that genetic basis has been obtained in response to precipitation difference among Spurpurea populations. The results help to understand the adaptation and evolution of Spurpurea to the special environment and the effect of climate change to this botanical system.     

Time-Course Studies on Accumulation of Hydrophilic Antioxidants to Different Stress Regimes Followed by Recovery in Contrasting Cultivars of Wheat

Under unpredictable climatic scenarios, drought is one of the major environmental constraints limiting plant growth and productivity in arid and semi-arid regions. Rapid recovery from drought is of paramount importance for the persistence and survival of different crops growing worldwide. The boiling soluble proteins, BSPs (proteins remaining soluble upon boiling in aqueous solution) forms an instrumental part of the response to water deficit conditions and might be of key importance for the survival of plants under unfavourable environmental conditions. These BSPs are typified by two unique properties: high hydrophilicity and high thermal stability. The main objective of the study was to determine drought-induced changes in the markers of oxidative stress along with modulation in the activity of the boiling soluble antioxidants in response to different stress regimes followed by re-watering in Triticum aestivum L. In this study, we determined the indices of oxidative stress (membrane injury index (MII) and lipid peroxidation in terms of malondialdehyde (MDA) content) and activities of boiling soluble antioxidant enzymes in seeds of sensitive and tolerant cultivars of wheat at different duration of stress (3, 6 and 10 days) followed by recovery (post stress harvest). Water content recorded a decline in the sensitive (PBW 343 and PBW 621) as well as tolerant (PBW 527 and PBW 175) cultivars in stress duration and cultivar dependent manner and this was reversed following re-watering in all the cultivars. Oxidative stress indicators also increased in all the cultivars at different stress intensities but this was reversed following re-watering in the tolerant cvs. PBW 175 and PBW 527. At 3 and 6 days, boiling soluble monodehydroascorbate reductase (BsMDAR), boiling soluble protein disulphide isomerase (BsPDI) activity increased in both the tolerant cvs. PBW 175 and PBW 527 whereas boiling soluble guaiacol peroxidase (BsGPX) increased in the sensitive cv. PBW 343. However, as the stress intensity increased to 10 days, BsMDAR, boiling soluble glutathione-S-transferase (BsGST) and BsGPX increased only in the tolerant cvs. PBW 175 and PBW 527, thus accentuating their cardinal roles in stress tolerance under harsh drought conditions. Upon re-watering the stress plants after 10 days, BsMDAR increased only in the tolerant cv. PBW 175. On the other hand, boiling soluble protein disulphide isomerase (BsPDI) increased in both the tolerant cv. PBW 175 and susceptible cv. PBW 343, but with a greater enhancement in the cv. PBW 175. Based upon our results, biochemical significance of the boiling soluble antioxidants in the cultivars of wheat differing in drought resistance during different stress intensities and recovery is discussed.     

Interspecific and intraspecific variation in seed size and germination requirements of Sarracenia (Sarraceniaceae)

Seed size and germination requirements of eight (of nine) Sarracenia species, and 13 populations of S. purpurea were studied. All species except for S. purpurea are restricted to the southeastern United States, whereas S. purpurea ranges across Canada, southward along the eastern United States into Maryland and Virginia (S. purpurea ssp. purpurea), and from New Jersey southward into northern Florida and the coast of the Gulf of Mexico (S. purpurea ssp. venosa). I tested the hypotheses that dormancy-breaking requirements vary predictably among species across a latitudinal gradient. I also sought to determine whether seed size and germination requirements were useful characters for resolving systematic and phylogenetic questions within this genus. Seed size varied significantly among species, but variability in seed size within S. purpurea exceeded the variability in seed size observed across all eight species studied. Seeds of all species are morphophysiologically dormant upon dispersal. Length of required cool, moist pretreatment varied among species, and germination in higher latitude populations is enhanced with longer pretreatment. In contrast, variability in germination requirements of subspecies, varieties, and populations of the geographically wide-ranging S. purpurea was not related clearly to geographic location (latitude or elevation). Germination requirements do not map onto a proposed phylogeny of Sarracenia, but observed differences in germination requirements of S. purpurea ssp. venosa var. burkii relative to other populations of S. purpurea support the recent proposal to elevate this variety to species status.     

Responses of pomegranate cultivars to severe water stress and recovery: changes on antioxidant enzyme activities,gene expression patterns and water stress responsive metabolites

The biochemical and molecular responses of five commercially well-known pomegranate cultivars to severe water stress were studied. The cultivars were subjected to 14-day water stress by withholding irrigation, followed by re-watering for 7 days. Results showed clear differences in metabolites contents and activities of antioxidant enzymes among various pomegranate cultivars during severe water stress and recovery. According to our results, increased accumulation of proline in pomegranate was not related to osmotic adjustment during severe water stress. Except for ‘Ghojagh’, leaves grown under severe water stress conditions showed symptoms of oxidative stress such as reduced chlorophyll concentration. The improved performance of ‘Ghojagh’ under drought stress may be associated with an efficient osmotic adjustment. The up- or down regulated expression of cytosolic glutathione reductase (cytosolic GR) and glutathione peroxidase were observed under drought conditions. Moreover, the suppressed expression of cytosolic GR was also noted. Comparatively, ‘Rabab’ exhibited higher antioxidant capacity and an efficient ROS-scavenging mechanism under drought stress. Lower levels of membrane lipid peroxidation in ‘Ghojagh’ and ‘Rabab’ under drought stress and the marked reduction of malondialdehyde concentration after re-watering represents that these cultivars have a good tolerance to drought stress. As a first step towards the study of the biochemical and molecular responses of pomegranate plants to water stress, this research provides new information into the mechanisms of drought tolerance in the plants.     

Comparative physiological and proteomic analysis of cultivated and wild safflower response to drought stress and re-watering

Drought is one of the major environmental stress that adversely affect the growth and development of oil seed plant, safflower. There is a limited knowledge on proteomic responses to support physiological, biochemical changes in how safflowers can regulate growth and metabolism under drought conditions and followed by re-watering. The changes in morphological, physiological, biochemical and proteomics of safflower genotypes (Carthamus tinctorius L.; Remzibey-05 and Linas, tolerant and sensitive cultivars, respectively, and C. oxyacantha M. Bieb., wild type) after exposure to drought and followed by re-watering have been examined. Drought negatively affected the shoot weight, water content, chlorophyll fluorescence, and biochemical parameters, including photosynthetic pigment, proline, MDA, and H₂O₂ contents and antioxidant enzyme activities in all genotypes, while the re-watering period allowed Remzibey-05 to recover, and it even provided the wild type completely recovered (approximately 100%). A total of 72 protein spots were observed as differently accumulated under treatments. The identified proteins were mainly involved in photosynthesis and carbohydrate, protein, defense, and energy metabolisms. Protein accumulation related to these metabolisms in Remzibey-05 were decreased under drought, while increased following re-watering. However, sensitive cultivar, Linas, could not exhibit an effective performance under drought and recovery when compared with other safflower genotypes. Supplementary InformationThe online version contains supplementary material available at (10.1007/s12298-021-00934-2).     

Proline Accumulation in Leaves of Periploca sepium via Both Biosynthesis Up-Regulation and Transport during Recovery from Severe Drought

Drought resistance and recovery ability are two important requisites for plant adaptation to drought environments. Proline (Pro) metabolism has been a major concern in plant drought tolerance. However, roles of Pro metabolism in plant recovery ability from severe drought stress are largely unexplored. Periploca sepium Bunge has gained increasing attention for its adaptation to dry environments. Here, we investigated Pro metabolism in different tissues of P. sepium seedlings in the course of drought stress and recovery. We found that leaf Pro metabolism response during post-drought recovery was dependant on drought severity. Pro biosynthesis was down-regulated during recovery from -0.4 MPa but increased continually and notably during recovery from -1.0 MPa. Significant correlation between Pro concentration and Δ1-pyrroline-5-carboxylate synthetase activity indicates that Glutamate pathway is the predominant synthesis route during both drought and re-watering periods. Ornithine δ-aminotransferase activity was up-regulated significantly only during recovery from −1.0 MPa, suggesting positive contribution of ornithine pathway to improving plant recovery capacity from severe drought. In addition to up-regulation of biosynthesis, Pro transport from stems and roots also contributed to high Pro accumulation in leaves and new buds during recovery from −1.0 MPa, as indicated by the combined analysis of Pro concentration and its biosynthesis in stems, roots and new buds. Except its known roles as energy, carbon and nitrogen sources for plant rapid recovery, significant positive correlation between Pro concentration and total antioxidant activity indicates that Pro accumulation can also promote plant damage repair ability by up-regulating antioxidant activity during recovery from severe drought stress.     

Photosynthetic characteristics in different peanut cultivars under conditions of drought and re-watering at seedling stage

Aims In China, peanut (Arachis hypogaea) is mainly cultivated in the semi-arid and rain-fed areas, and drought is the most prominent environmental stress to its growth. However, studies on the physiological responses of different peanut cultivars to drought and re-watering are lacking. Our objectives were to investigate the relationship between photosynthetic characteristics and drought tolerance, and to explore the ability to recover from drought damage in different peanut cultivars.
Methods A pot experiment was conducted with artificial water stress treatment, and the photosynthetic characteristics were determined in twelve peanut cultivars under the conditions of drought stress and re-watering at the seedling stage. The drought tolerance was assessed by drought resistance coefficient of biomass in seedling. The recovery capacity was assessed by compensatory growth of plant.
Important findings Five cultivars, including ‘Shanhua 11’, ‘Rugaoxiyangsheng’, ‘A596’, ‘Shanhua 9’, and ‘Nongda 818’, showed over-compensatory growth after re-watering, and their capacity of compensatory growth had significant positive correlation with drought tolerance (p < 0.01). The net photosynthetic rate (P_n), stomatal conductance (G_s), intercellular CO₂ concentration (C_i), maximum photochemical efficiency (F_v/F_m), PSII actual quantum yield (ΦPSII), and photochemical quenching coefficient (q_P) all decreased over the course of drought stress, and then increased following re-watering, with the amplitude of changes being smaller in the more drought tolerant cultivars. Seven days of drought did not result in significant differences in the photosynthetic characteristics among majority of the peanut cultivars tested (p > 0.05). After 14 days of drought, the values of photosynthetic variables differed significantly among the peanut cultivars with different drought tolerance (p < 0.05). The values of P_n, G_s, Φ_PSII, F_v/F_m, and q_P in the cultivars ‘Shanhua 11’, ‘Rugaoxiyangsheng’, ‘A596’, and ‘Shanhua 9’fully recovered five days after re-watering, while those in the cultivars ‘79266’, ‘ICG6848’, ‘Baisha 1016’, and ‘Hua 17’ did not fully recover even after 10 days of re-watering; the values of those photosynthetic variables were significantly greater (p < 0.05) in the more drought tolerant cultivars following re-watering. Correlation analysis showed that the drought tolerance was significantly and positively correlated with P_n, Φ_PSII, F_v/F_m, and q_P after 14 days of drought stress and after five days of re-watering, respectively (p < 0.01). Therefore, under drought stress at 40% of relative water content (RWC) for 14 days and after five days of re-watering at the seedling stage, the P_n, Φ_PSII, F_v/F_m, and q_P could be used for identifying the level of damage and recovery capacity of peanut cultivars. The cultivar ‘Shanhua 11’ can be used as a reference for drought adaptability identification in peanut.     

过表达NtMYB4a基因增强烟草抗旱能力

为探究转录因子NtMYB4a参与调控烟草(Nicotiana tabacum)抵抗干旱胁迫的能力,以NtMYB4a过表达株系(OE)、敲除株系(KO)和野生型(WT)为材料,通过盆栽实验模拟自然干旱胁迫,对比分析三个株系在干旱胁迫0、2、4、6、8 d和复水2 d后的光合特征、根系活力、叶绿素、脯氨酸(Pro)和丙二醛(MDA)含量以及抗氧化酶活性等指标。结果表明,OE株系的净光合速率(Pn)、根系活力、叶绿素含量、Pro含量以及SOD、POD和CAT活性均显著高于WT株系,而蒸腾速率(Tr)、气孔导度(Gs)、MDA含量则显著低于WT株系;KO株系多数时期Pn、根系活力、叶绿素含量、Pro含量及SOD、POD和CAT活性显著低于WT株系,Tr、Gs、MDA含量则显著高于WT株系。因此,超表达NtMYB4a可能通过提高烟草的光合能力、根系活力和抗氧化酶活性,减少细胞膜损伤来提高烟苗抗旱性。     

干旱-复水处理对杠柳幼苗光合作用及活性氧代谢的影响

采用人工控制土壤水分试验,以80%田间持水量处理为对照,研究了3次干旱-复水处理对2年生杠柳幼苗叶片光合作用,根、茎、叶膜脂过氧化和抗氧化系统的影响.结果表明: 在干旱条件下, 杠柳叶片相对含水量和光合速率(P_n)显著降低,光合色素含量升高. 干旱复水后,叶片相对含水量完全恢复,反映了杠柳较强的旱后修复能力;叶绿素含量和P_n均明显高于对照,表现出补偿效应,适度干旱诱导了杠柳的抗旱适应性.干旱胁迫使P_n下降,以气孔限制为主,但在中午发生了非气孔限制;幼叶、新茎和细根中的超氧阴离子产生速率升高,丙二醛含量则降低,说明这些幼嫩组织未受到氧化伤害.不同器官中SOD、CAT和POD活性及变化趋势不同,以细根的3种保护酶的反应最为灵敏,说明细根是杠柳适应干旱环境的重要器官.器官间的相互合作与协调使杠柳能有效地适应干湿交替的干旱环境.     

苗期干旱及复水条件下不同花生品种的光合特性

为探索不同花生(Arachis hypogaea)品种的旱后恢复能力, 研究花生品种耐旱性与光合特性的关系, 通过盆栽土壤水分控制实验, 测定了12个花生品种苗期对干旱胁迫与复水过程的光合响应特征, 并讨论了所测各性状参数与抗旱性强弱的关系, 包括对水分胁迫伤害的修复能力。结果表明, 根据苗期生物量抗旱系数, ‘山花11号’、‘如皋西洋生’、‘A596’、‘山花9号’、‘农大818’的抗旱性较强, 且复水后植株产生超补偿生长效应, 补偿生长能力与抗旱性呈极显著正相关。叶片净光合速率(P_n)、气孔导度(G_s)、胞间CO₂浓度(C_i)、最大光化学效率(F_v/F_m)、实际光化学效率(Φ_PSII)、光化学猝灭系数(q_P)随干旱进程逐渐降低, 复水后逐渐增加, 抗旱性强的花生品种变幅较小。干旱7天, 大多数花生品种的光合参数值未有显著性差异。干旱14天, 抗旱性越强的花生品种光合参数值越高, 不同抗旱性花生品种的光合参数值有显著差异。‘山花11号’、‘如皋西洋生’、‘A596’、‘山花9号’的P_n、G_s、Φ_PSII、F_v/F_m、q_P在复水5天时恢复至对照水平, 复水10天时超过对照, ‘79266’、‘ICG6848’、 ‘白沙1016’、‘花17’在复水10天时仍未达到对照水平, 复水过程中抗旱性强的品种的光合参数显著高于抗旱性弱的品种。相关分析表明, 干旱胁迫14天和复水5天后, 花生的P_n、Φ_PSII、F_v/F_m、q_P与品种抗旱性呈极显著正相关。因此, 可在苗期用40%土壤相对含水量胁迫14天及复水5天时花生的P_n、Φ_PSII、F_v/F_m、q_P鉴定品种的干旱伤害程度及修复能力, ‘山花11号’可作为强干旱适应性鉴定的标准品种。     

A root proteomics-based insight reveals dynamic regulation of root proteins under progressive drought stress and recovery in <Emphasis Type="Italic">Vigna radiata</Emphasis> (L.) Wilczek

To understand the complex drought response mechanism in crop plants, a systematic root proteomics approach was adopted to identify and analyze the expression patterns of differentially expressed major root proteins of Vigna radiata during short-term (3 days) and consecutive long-term water-deficit (6 days) as well as during recovery (6 days after re-watering). Photosynthetic gas exchange parameters of the plant were measured simultaneously during the stress treatment and recovery period. A total of 26 major protein spots were successfully identified by mass spectrometry, which were grouped according to their expression pattern during short-term stress as significantly up-regulated (9), down-regulated (10), highly down-regulated, beyond detection level of the software (2) and unchanged (5). The subsequent changes in the expression patterns of these proteins during long-term stress treatment and recovery period was analyzed to focus on the dynamic regulation of these functionally important proteins during progressive drought and recovery period. Cytoskeleton-related proteins were down-regulated initially (3d) but regained their expression levels during subsequent water-deficit (6d) while glycoprotein like lectins, which were primarily known to be involved in legume–rhizobia symbiosis, maintained their enhanced expression levels during both short and long-term drought treatment indicating their possible role in drought stress response of legumes. Oxidative stress-related proteins including Cu/Zn superoxide dismutase, oxidoreductase and aldehyde reductase were also up-regulated. The analyses of the dynamic regulation of these root proteins during short- and long-term water-deficit as well as recovery period may prove crucial for further understanding of drought response mechanisms in food legumes.     

Phenology and polyploidy in annual Brachypodium species (Poaceae) along the aridity gradient in Israel

Local adaptation of plants along environmental gradients provides strong evidence for clinal evolution mediated by natural selection. Plants have developed diverse strategies to mitigate stress, for example, drought escape is a phenological strategy to avoid drought stress, while polyploidy was proposed as a genomic adaptation to stress. Polyploidy as an adaptation to aridity (an environmental parameter integrating temperature and precipitation) was previously documented in annual Brachypodium spp. (Poaceae) in the Western Mediterranean. Here, we examined whether polyploidy or phenology are associated with aridity in annual Brachypodium spp. along the aridity gradient in the Eastern Mediterranean. Using flow cytometry, we determined ploidy levels of plants from natural populations along the Israeli gradient, spanning ∼424 km from mesic Mediterranean to extreme desert climates. In a common garden we recorded time of seedling emergence, flowering and senescence. We tested whether the proportion of allotetraploids in the populations and phenological traits were associated with aridity. Contrary to a previous study in the Western Mediterranean, we found no effect of aridity on the proportion of allotetraploids and diploids within populations. Interestingly, phenology was associated with aridity: time of emergence was later, while flowering and senescence were earlier in desert plants. Our results indicate that in the Eastern Mediterranean, adaptation of Brachypodium to aridity is mediated mainly by phenology, rather than ploidy level. Therefore, we suggest that genome duplication is not the main driver of adaptation to environmental stress; rather, phenological change as a drought escape mechanism may be the major adaptation.     

Differential regulation of aquaporins, small GTPases and V-ATPases proteins in rice leaves subjected to drought stress and recovery

Mechanisms of drought tolerance are complex, interacting, and polygenic. This paper describes patterns of gene expression at precise physiological stages of drought in 35-day-old seedlings of Oryza sativa cv. Nipponbare. Drought was imposed gradually for up to 15 days, causing abscisic acid levels to rise and growth to cease, and plants were then re-watered. Proteins were identified from leaf samples after moderate drought, extreme drought, and 3 and 6 days of re-watering. Label-free quantitative shotgun proteomics resulted in identification of 1548 non-redundant proteins. More proteins were down-regulated in early stages of drought but more were up-regulated as severe drought developed. After re-watering, there was notable down regulation, suggesting that stress-related proteins were being degraded. Proteins involved in signalling and transport became dominant as severe drought took hold but decreased again on re-watering. Most of the nine aquaporins identified were responsive to drought, with six decreasing rapidly in abundance as plants were re-watered. Nine G-proteins appeared in large amounts during severe drought and dramatically degraded once plants were re-watered. We speculate that water transport and drought signalling are critical elements of the overall response to drought in rice and might be the key to biotechnological approaches to drought tolerance.     

Probing the responses of barley cultivars (Hordeum vulgare L.) by chlorophyll a fluorescence OLKJIP under drought stress and re-watering

The main objective of this study was to evaluate the effects of drought and re-watering on 10 varieties of barley (Hordeum vulgare L.) originating from Morocco. Five varieties obtained from the National Institute of Agricultural Research (INRA) of Morocco and five landraces (local varieties defined by high stress tolerance, high yield stability, an intermediate yield and low-input demand) collected at five localities in the south of Morocco were used in the present study. After 2 weeks of growth, drought stress was initiated by withholding water for 2 weeks followed by 1 week of re-watering. The polyphasic OJIP fluorescence transient was used to evaluate photosystem II (PSII) criteria at the end of the first week of drought stress (moderate drought), at the end of the second week (severe drought) and the end of the recovery phase. Drought and re-watering had little effect on the maximum quantum yield of primary photochemistry φ_Po(=F_V/F_M). The photosynthetic performance index (PI) is the product of an antenna, reaction center and electron transport dependent parameter. It revealed differences between varieties as a function of drought and re-watering. For the screening for drought stress tolerance, changes in the PI during a 2-week drought stress treatment were analysed and a new parameter was defined: the drought factor index (DFI) = log(PI_week 1/PI_control) + 2 log(PI_week 2/PI_control). The DFI of the tested varieties correlated with their drought tolerance. Another parameter that was analysed was the relative water content. It decreased during the drought stress treatment varying between 61% and 78.2% at the end of the drought period. During the subsequent recovery period, it increased in a species-dependent manner (65.1–94.1%). A third parameter studied were changes in the initial fluorescence rise. The fluorescence rise during the first 300 μs (L-band) can give information on the energetic connectivity between PSII units whereas changes in the rise during the first 2 ms (K-band) offer information on developing limitations on the donor side of PSII. Changes in respectively the L and K-bands of the fluorescence transients OJIP were shown to have predictive value with respect to the vitality of leaves and the tolerance of the varieties to drought stress.     

Drought stimulation by hypocotyl exposure altered physiological responses to subsequent drought stress in peanut seedlings

Drought stress occurring at the seedling stage of peanut (Arachis hypogaea L.) plants is a limiting factor resulting in considerable reductions in production. Plants can improve their resistance to subsequent stresses after experiencing an initial stress. The aim of this study was to explore the possible role of drought priming by hypocotyl exposure in alleviating subsequent severe drought stress in peanut. Hypocotyl exposure in peanut seedlings as a drought stimulus induced xerophytophysiological regulation, shown by induced osmotic adjustment, activated antioxidant enzymes, anthocyanin accumulation, up-regulation of Gdi-15 and fewer amyloplasts. The seedlings primed by hypocotyl exposure showed improved leaf water retention and reduced proline content when exposed to subsequent drought stress. The alleviated oxidative damage and lower antioxidant enzyme activities indicated rapid acclimation following past hypocotyl exposure and further defenses against subsequent drought stress by retaining ‘memories’ to enable more rapid or stronger physiological responses. The improved leaf photosynthesis and low photosynthetic hysteresis as drought ended indicated a positive effect of drought priming in peanut seedlings. The peanut seedlings ‘remembered’ the xerophytophysiological responses caused by the prior drought stimulation from hypocotyl exposure and displayed quicker and more potent physiological responses to following drought stress. The results showed that hypocotyl exposure could help peanut seedlings survive the severe environments that occurred in the later growth stages.     

Different responses of photosystem II and antioxidants to drought stress in two contrasting populations of Sour jujube from the Loess Plateau,China

Sour jujube (Zizyphus jujuba Mill. var. spinosus (Bge.) Hu) has gained considerable attention for its adaptation to drought prone environments. To characterize the physiological and biochemical basis of this drought adaptation, the effects of drought stress on Sour jujube seedlings were investigated in a greenhouse. Two contrasting populations were employed in our study, which were from the wet (YL) and dry (SB) climatic regions in the Loess Plateau of China. Results showed that SB exhibited lower water consumption and growth inhibition, but higher water use efficiency than YL under drought stress, indicating that growth of the wet-climate population is more sensitive to drought stress. SB exhibited higher non-photochemical quenching (NPQ) during progressive soil drying, higher photochemical quenching (qP) during the sustained water supply stage, and higher ΔF/\(F_{\rm m}^\prime\) and qP during a re-watering period than YL. These results further indicate that the dry-climate population possesses better PSII efficiency under adverse conditions. YL showed larger increases in the production rate of superoxide anions, hydrogen peroxide, and hydroxyl radicals than SB during the progressive soil drying stage, indicating that SB suffered from less oxidative damage than YL. Antioxidant enzymes including catalase, ascorbate peroxidase, peroxidase and glutathione reductase, and antioxidants including carotenoids, flavonoids and proline; when these interact, they contribute greatly to the antioxidant capacity of the dry-climate population. Taken together, the better photosynthetic potential and antioxidant capacity contribute to the better performance of Sour jujube from the dry-climate, providing useful information for understanding the drought tolerance mechanisms of Sour jujube.     

Genetic diversity pattern of Stipa purpurea populations in the hinterland of Qinghai–Tibet Plateau

Stipa purpurea is among constructive endemic species in alpine meadow and steppe on the Qinghai–Tibet Plateau. To reveal the genetic diversity of this species and its relationship with geographic distribution pattern, we sampled eight populations across a northward transect with an increasing aridity gradient in the hinterland of Qinghai–Tibet Plateau. Their genetic diversity was quantified using eight intersimple sequence repeat (ISSR) primers. We found that S. purpurea had relatively low genetic diversity ( H _e = 0.135) but significant genetic differentiation among populations ( G _st = 0.391), indicating relatively more genetic diversity retained within populations. A Mantel test revealed a significant relationship between genetic and geographic distance in the S. purpurea populations. The genetic diversity tended to decrease with increasing latitude and longitude, while no significant relationship was found between genetic diversity and altitude, suggesting the possible influences of humidity and temperature on genetic diversity of alpine plant. We propose conservation measures for this plant on the plateau.