Genetic analysis of toxic aluminum ion tolerance in barley

The genetic control of high tolerance of toxic aluminum ions in barley Hordeum vulgare L. has been studied. Cultivar Faust I (c-24612) and accession c9736 from Karelia have been compared with aluminum-sensitive cv. Colsess IV (accession c-24626). Analysis of F₁, F₂BC₁, F₃, and F₄ progenies has shown that the development of roots of cv. Faust I in water medium with aluminum ions is determined by one (Alp _F1) or two (Alp _F1 and Alp _F2) genes. The development of roots of accession c9736 is determined by two genes, Alp _K1 and Alp _K2. The genes have not been not tested for nonidentity. The high tolerance of Faust I shoots are determined by one major tolerance factor and one dominant inhibitor gene, which hampers the manifestation of the dominant tolerance gene. The penetrance of the inhibitor gene may be incomplete. The aluminum sensitivity of roots and 7-day shoots of cv. Faust I is determined by different genetic factors. The response of barley plants to aluminum ions may be determined by small-effect genes.     

A new aluminum tolerance gene located on rye chromosome arm 7RS

Rye has one of the most efficient groups of genes for aluminum tolerance (Alt) among cultivated species of Triticeae. This tolerance is controlled by, at least, three independent and dominant loci (Alt1, Alt2, and Alt3) located on chromosome arms 6RS, 3RS, and 4RL, respectively. The segregation of Alt genes and several random amplified polymorphic DNA (RAPD), Secale cereale inter-microsatellite (SCIM), and Secale cereale microsatellite (SCM) markers in three F(2) between a tolerant cultivar (Ailés) and a non-tolerant inbred line (Riodeva) were studied. The segregation ratio obtained for aluminum tolerance in the three F(2) populations analyzed was 3:1 (tolerant:non-tolerant), indicating that tolerance is controlled by one dominant locus. SCIM811(1376) was linked to an Alt gene in the three F(2) populations studied, and three different SCIMs and one RAPD (SCIM811(1376), SCIM812(626), SCIM812(1138), and OPQ4(725)) were linked to the Alt gene in two F(2) populations. This result indicated that the same Alt gene was segregating in the three crosses. SCIM819(1434) and OPQ4(578) linked to the tolerance gene in one F(2) population were located using wheat-rye ditelosomic addition lines on the 7RS chromosome arm. The Alt locus is mapped between SCIM819(1434) and the OPQ4(578) markers. Two microsatellite loci (SCM-40 and SCM-86), previously located on chromosome 7R, were also linked to the Alt gene. Therefore, the Alt gene segregating in these F(2) populations is new and probably could be orthologous to the Alt genes located on wheat chromosome arm 4DL, on barley chromosome arm 4HL, on rye chromosome arm 4RL, and rice chromosome 3. This new Alt gene located on rye chromosome arm 7RS was named Alt4. A map of rye chromosome 7R with the Alt4 gene, 16 SCIM and RAPD, markers and two SCM markers was obtained.     

Salt tolerance of barley: Relations between expression of isoforms of vacuolar Na<Superscript>+</Superscript>/H<Superscript>+</Superscript>-antiporter and <Superscript>22</Superscript>Na<Superscript>+</Superscript> accumulation

Two barley cultivars (Hordeum vulgare L., cvs. Elo and Belogorskii) differing in salt tolerance were used to study ²²Na⁺ uptake, expression of three isoforms of the Na⁺/H⁺ antiporter HvNHX1-3, and the cellular localization of these isoforms in the elongation zone of seedling roots. During short (1 h) incubation, seedling roots of both cultivars accumulated approximately equal quantities of ²²Na⁺. However, after 24-h incubation the content of ²²Na⁺ in roots of a salt-tolerant variety Elo was 40% lower than in roots of the susceptible variety Belogorskii. The content of ²²Na⁺ accumulated in shoots of cv. Elo after 24-h incubation was 6.5 times lower than in shoots of cv. Belogorskii and it was 4 times lower after the salt stress treatment. The cytochemical examination revealed that three proteins HvNHX1-3 are co-localized in the same cells of almost all root tissues; these proteins were present in the tonoplast and prevacuolar vesicles. Western blot analysis of HvNHX1-3 has shown that the content of isoforms in vacuolar membranes increased in response to salt stress in seedling roots and shoots of both cultivars, although the increase was more pronounced in the tolerant cultivar. The content of HvNHX1 in the seedlings increased in parallel with the enhanced expression of HvNHX1, whereas the increase in HvNHX2 and HvNHX3 protein content was accompanied by only slight changes in expression of respective genes. The results provide evidence that salt tolerance of barley depends on plant ability to restrict Na⁺ transport from the root to the shoot and relies on regulatory pathways of HvNHX1-3 expression in roots and shoots during salt stress.     

Modeling uptake of cadmium from solution outside of root to cell wall of shoot in rice seedling

Barley (Hordeum vulgare L.) is well known for its relatively high salt tolerance among cereal crops. However, the genetic variation of cultivated barley becomes narrower due to continuous artificial selection and breeding processes. Compared with cultivated barley, wild barley contains wider genetic variation and abundant sources for abiotic stress tolerance, considering as an elite resource for mechanism study on salt tolerance. In this study, Tibetan wild barley accession XZ113 identified with high salt tolerance, was used to investigate ionic responses and to identify proteins involved in salt tolerance in roots and shoots at early stage of salt stress, during 48 h. Exposed to salinity, shoot growth is more sensitive than root growth. Conversely, K/Na ratio in the shoots was larger than that in the roots, and both were above 1.0. Steady-state K⁺ flux experiment showed XZ113 had a strong K⁺-retaining ability under salt stress, maybe contributing to its good performance of the absolute growth rate. Proteomic results suggested that monodehydroascorbate reductase and peroxidases related to reactive oxygen species scavenging in the roots and phosphoglycerate kinase, triosephosphate isomerase and sedoheptulose-1,7-bisphosphatase associated with photosynthesis and metabolisms in the shoots, played important roles in salt tolerance at early stage of salinity in wild barley.     

Growth,ionic response,and gene expression of shoots and roots of perennial ryegrass under salinity stress

Growth, ionic responses, and expression of candidate genes to salinity stress were examined in two perennial ryegrass accessions differing in salinity tolerance. The salinity tolerant (PI265349) and sensitive accessions (PI231595) were subjected to 75-mM NaCl for 14 days in a growth chamber. Across two accessions, salinity stress increased shoot dry weight and concentrations of malondialdehyde (MDA) and Na⁺ in the shoots and roots, but decreased shoot Ca²⁺ and root K⁺ concentrations. Salinity stress also increased root expressions of SOS1, PIP1, and TIP1. Plant height and chlorophyll content were unaffected by salinity stress in the tolerant accession but significantly decreased in the sensitive accession. Shoot MDA content did not change in the tolerant accession but increased in the sensitive accession. A more dramatic increase in Na⁺ was found in the roots of the sensitive accession. Relative to the control, salinity stress reduced expression of SOS1, NHX1, PIP1, and TIP1 in the shoots but increased expression of these genes in the roots of the tolerant accession. Expression levels of SOS1 increased in the roots and expression of NHX1 increased in the shoots but decreased in the roots of the sensitive accession under salinity stress. A decline in PIP1 expression in the shoots and dramatic increases in TIP expression in both shoots and roots were found in the sensitive accession under salinity stress. The results suggested maintenance of plant growth and leaf chlorophyll content, lesser Na⁺ accumulation in the roots, and lower lipid peroxidation in the shoots which could be associated with salinity tolerance. The decreased expressions of SOS1, NHX1, and TIP1 in the shoots, and increased expressions of NHX1 and PIP1 in the roots might also be related to salinity tolerance in perennial ryegrass.     

Phosphorus export from roots to shoots of barley, buckwheat and rape seedlings with different P status

Seedlings of barley (Hordeum vulgare L. cvs Salka and Zita), buckwheat (Fagopyrum esculentum Moench) and rape (Brassica napus L. ssp. napus cv. Line) were grown in complete nutrient solutions with 8 or 10 different P concentrations in the range of 0–2 mM. Phosphate export from roots to shoots was determined from the amount of ³²P (or ³³P) absorbed and exported to shoots in 1 h from a nutrient solution containing 0.1 mM radiolabelled phosphate. P export was also determined in the presence of a metabolic uncoupler (DNP, 2.4-dinitrophenol) and a protein synthesis inhibitor (CH, cycloheximide). Phosphorus export from roots to shoots reached a maximum at a certain optimum level of phosphorus in shoots and roots, and decreased at both higher and lower P levels. Maxinmm P export was 1.7 ± 0.2 and 4.5 ± 0.5 (mean ±se of the three species) times higher than the P export at the lowest and highest [P]_root, respectively. Hill plots as well as plots of the untransformed decreasing P export vs root or shoot P concentrations above the optimum were linear and had high correlation coefficients. The Hill coefficient (n_H) based on [P]_root, was —7.7 for barley cv. Salka and varied between -3.8 and -4.5 for the other species. Based on [P]_shootot n_H was—16.1 for barley cv. Salka, -3.7 for barley cv. Zita and -6.4 for the two dicotyledonous species. Relative to the amount of P simultaneously absorbed by the root system, the import of P per unit shoot weight decreased linearly over the whole range of shoot P concentrations in the dicotyledonous species. In contrast, the relative import of P per unit shoot weight of the two barley cultivars increased at low levels of [P]_shoot and decreased at higher levels. DNP and CH almost eliminated P export from roots to shoots of seedlings with low or high P status. In seedlings with medium P status only 60 to 75% of the P export was affected.     

Ethylene-induced putrescine accumulation modulates K+ partitioning between roots and shoots in barley seedlings

We investigated the cause and effect relationships among ethylene, polyamines, and K⁺ in barley ( Hordeum vulgare L. cv. Amagi) seedlings. Application of 1-aminocyclopropane-1-carboxylic acid (ACC), a precursor of ethylene, to the growth medium caused a decrease in K⁺ concentration in roots and an increase in shoots. Addition of ACC induced putrescine accumulation in roots, while spermidine and spermine levels remained unchanged. Exogenous supply of putrescine led to putrescine accumulation and reduced K⁺ concentration. Application of Co²⁺, an inhibitor of ethylene biosynthesis, together with ACC, inhibited putrescine accumulation with a decrease in K⁺ concentration in roots. ACC-treated roots showed K⁺ uptake capacity equivalent to that of control roots, implying that the majority of K⁺ is translocated to shoots. These results suggest that ethylene regulates K⁺ partitioning between roots and shoots through the level of accumulation of putrescine in barley seedlings.     

Acquisition of aluminum tolerance in Saccharomyces cerevisiae by expression of the BCB or NtGDI1 gene derived from plants

Eleven aluminum stress-induced genes derived from plants (wheat, Arabidopsis and tobacco) were introduced into Saccharomyces cerevisiae to test if expression of these genes confers Al tolerance. Al sensitivity tests showed that expression of two genes, either an Arabidopsis gene for blue copper binding protein (BCB), or a tobacco gene for the GDP dissociation inhibitor (NtGDI1), conferred Al tolerance. Determinations of total content and localization of Al ions in these transformants suggested that the BCB gene product functions in restricting Al uptake, while expression of the NtGDI1 gene promotes release of Al ions after uptake.     

RFLP markers linked to scald (Rhynchosporium secalis) resistance gene Rh2 in barley

Rhynchosporium secalis is the causal organism of barley scald disease. A number of resistance genes against the fungus are well known; one of them, the single dominant Rh2 resistance gene, has been mapped on the linkage map of barley using RFLP (restriction fragment length polymorphism) markers. The Rh2 gene was located on the distal part of chromosome arm 1S co-segregating with the RFLP marker CDO545 in 85 doubled-haploid progeny plants. The spring barley test population used was a cross between the 6-rowed American spring barley cv Atlas, C.I. 4118, carrying the Rh2 resistance gene, and a Bavarian 2-rowed malting barley cv Steffi, susceptible for R. secalis. The assessment of resistance versus susceptibility was based on artificial infections with a one-spore inoculum in greenhouse tests and with pathotype mixtures in field tests. By testing a pathotype mixture of German origin good resistance was found for the Rh2 gene in the field.     

Root responses to cereal cyst nematode (Heterodera avenae) in hosts with different resistance genes

The development of cereal cyst nematode (CCN; Heterodera avenae ) induced syncytia in the host roots of infected resistant bread wheat ( Triticum aestivum cv. AUS10894), diploid wheat ( Aegilops tauschii ), barley ( Hordeum vulgare cv. Chebec and cv. Galleon) and in the susceptible wheat cv. Meering and barley cv. Clipper were studied over a period of 13 d. The resistance to CCN in these cereal plants is conferred by the resistance genes Cre1 in the wheat cv. AUS10894, Cre3 in A. tauschii , Ha2 in barley cv. Chebec and Ha4 in barley cv. Galleon. Anatomical observations were made on the development of the syncytia in CCN-infected wheat and barley roots, which carry each of these four sources of resistance genes. Accelerated development of the syncytia in resistant plants, especially in the barley cultivars, was observed. The sites of syncytia development in susceptible wheat and barley were also closely associated with the vascular tissues in the stele, but less so in the resistant plants. The syncytia in the infected susceptible wheat and barley were also metabolically active at day 13. By contrast, the syncytia of resistant wheat plants carrying the Cre1 or Cre3 genes remained extensively vacuolated and less metabolically active. In barley plants with the Ha2 or Ha4 genes, the syncytia appeared non-functional and in early stages of degeneration by day 13 after inoculation.     

Barley Cbf3 gene identification,expression pattern,and map location

Although cold and drought adaptation in cereals and other plants involve the induction of a large number of genes, inheritance studies in Triticeae (wheat [Triticum aestivum], barley [Hordeum vulgare], and rye [Secale cereale]) have revealed only a few major loci for frost or drought tolerance that are consistent across multiple genetic backgrounds and environments. One might imagine that these loci could encode highly conserved regulatory factors that have global effects on gene expression; therefore, genes encoding central regulators identified in other plants might be orthologs of these Triticeae stress tolerance genes. The CBF/DREB1 regulators, identified originally in Arabidopsis as key components of cold and drought regulation, merit this consideration. We constructed barley cDNA libraries, screened these libraries and a barley bacterial artificial chromosome library using rice (Oryza sativa) and barley Cbf probes, found orthologs of Arabidopsis CBF/DREB1 genes, and examined the expression and genetic map location of the barley Cbf3 gene, HvCbf3. HvCbf3 was induced by a chilling treatment. HvCbf3 is located on barley chromosome 5H between markers WG364b and saflp58 on the barley cv Dicktoo x barley cv Morex genetic linkage map. This position is some 40 to 50 cM proximal to the winter hardiness quantitative trait locus that includes the Vrn-1H gene, but may coincide with the wheat 5A Rcg1 locus, which governs the threshold temperature at which cor genes are induced. From this, it remains possible that HvCbf3 is the basis of a minor quantitative trait locus in some genetic backgrounds, though that possibility remains to be thoroughly explored.     

盐胁迫下柚和橘幼苗体内矿质元素变化的比较研究

采用沙培法,对盐胁迫下坪山柚和福橘幼苗体内矿质元素的变化进行了研究。结果表明,随着NaCl浓度的增加,坪山柚和福橘幼苗根部及地上部Na^＋、Cl-含量增加,且相同浓度下,福橘比坪山柚高。40mmol／L NaCI胁迫下,坪山柚和福橘幼苗地上部的K^＋、Fe含量,根部的Ca^2＋、Mg^2＋、Zn含量显著下降,而根部Fe含量及地上部Zn含量显著增加。随NaCl浓度增大,坪山柚根部K^＋含量,地上部Ca^2＋、Mg^2＋含量变化不明显,而福橘根部、地上部上述离子含量在NaCl浓度≥160mmol／L时均显著下降。因此,根部K^＋含量,地上部Ca^2＋、Mg^2＋含量存在品种问差异,或许可作为耐盐性鉴定指标。NaCl胁迫降低坪山柚和福橘幼苗根部及地上部P、Mn含量,而Cu含量在较高浓度NaCl胁迫下显著增加。NaCl胁迫明显降低坪山柚和福橘幼苗地上部K^＋／Na^＋、Ca^2＋／Na^＋和Mg^2＋／Na^＋值,其中K^＋／Na^＋值的变化可考虑作为柑橘耐盐性鉴定的指标。     

Growth and Nutrient Uptake by Barley (Hordeum vulgare L. cv Herta): Studies Using an N-(2-Hydroxyethyl)ethylenedinitrilotriacetic Acid-Buffered Nutrient Solution Technique (I. Zinc Ion Requirements)

The critical range of Zn2+ activity in nutrient solution required for optimum growth of barley (Hordeum vulgare L. cv Herta) was studied using the synthetic chelating agent N-(2-hydroxyethyl)ethylenedinitrilotriacetic acid to buffer micronutrient metal ions. The activity of Zn2+ was varied over a wide range from approximately 0.1 x 10-11 to 22 x 10-11 M Zn2+. The dry weight of barley shoots reached a maximum at Zn2+ activities above approximately 3 x 10-11 M and was clearly depressed when Zn2+ activities were below about 1 x 10-11 M. The relationship in shoots between dry weight and Zn concentrations supports the view that there is a critical Zn concentration of about 25 [mu]g g-1 dry weight in whole shoots of barley seedlings. When Zn2+ activities in solution were near or below approximately 3 x 10-11 M, barley shoots accumulated higher concentrations of P, Mn, Ca, Mg, and Na, whereas Cu concentrations were reduced. P and Mn began to accumulate in the shoots before differences in dry weights were apparent and provided the earliest index of Zn deficiency. In Zn-deficient roots, concentrations of Ca and Mg increased by 25 to 30%, and those of Fe and Mn more than doubled. Zn appears to play a special role in regulating uptake of several mineral nutrients in barley.     

Inheritance and chromosome locations of scald-resistance genes derived from Iranian and Turkish wild barleys

 A set of advanced backcross barley lines derived from crosses between cv Clipper and different Iranian and Turkish wild barleys, which are homozygous for particular isozyme-marked donor intervals, was screened for resistance to barley scald. Eight lines that consistently exhibited scald resistance were identified, and genetic analysis indicated that single dominant genes encoded resistance in five of the lines, single recessive genes were present in two lines, and a pair of unlinked, dominant genes encoded the resistance in the last line. Linkage between the scald-resistance gene and the isozyme marking the introgressed donor chromosome interval was detected in four lines, allowing the chromosome locations of these resistance genes to be determined. One such resistance gene resides on barley chromosome 5, to which no other scald-resistance genes have been mapped; this gene has been designated Rrs14. A survey of the effectiveness of the eight resistance genes against a set of virulent pathotypes of the scald pathogen revealed that four of the lines were completely resistant to all of them. In two instances, the recovery of more than one scald-resistance gene from a single original donor parent could be demonstrated. These scald-resistance genes should provide additional opportunities for breeding programs that aim to develop scald-resistant barley cultivars. Received: 8 August 1996/Accepted: 27 September 1996     

Aluminum triggers broad changes in microRNA expression in rice roots

MicroRNAs are small 21-nucleotide RNA molecules with regulatory roles in development and in response to stress. Expression of some plant miRNAs has been specifically associated with responses to abiotic stresses caused by cold, light, iron, and copper ions. In acid soils, aluminum solubility increases, thereby causing severe damage to plants. Although physiological aspects of aluminum toxicity in plants have been well characterized, the molecular mediators are not fully elucidated. There have been no reports about miRNA responses to aluminum stress. Modulation of miRNA expression may constitute a key element to explain the mechanisms implicated in aluminum toxicity and tolerance. We examined the expression of at least one miRNA member from each miRNA family in rice roots of Oryza sativa spp indica cv. Embrapa Taim and Oryza sativa spp japonica cv. Nipponbare under high concentrations of aluminum. Forty-six miRNA families were effectively detected by quantitative PCR. Among these, 13 were down-regulated and six were up-regulated in roots of the Nipponbare cultivar after 8 h of aluminum treatment. In roots of the Embrapa Taim cultivar, five miRNAs were down-regulated and three were up-regulated. Analyses of their putative targets suggest that these rice miRNAs are involved in the regulation of various metabolic pathways in response to high concentrations of aluminum.     

Genetic control of NaCl tolerance in seedlings of durum wheat <Emphasis Type="Italic">Triticum durum</Emphasis> Desf. accessions

The genetic control of tolerance to NaCl (0.7 MPa, 9.8 g/l) was studied in six durum wheat accessions from the world collection of the Vavilov Institute of Plant Industry. Analysis of F₁, F₂, and F₃ of the crosses between tolerant forms and a in accessions k-17227 and k-10930susceptible tester has demonstrated that a high salt tolerance is determined by one dominant gene; in accession k-46660, by three independent dominant genes; and in accessions k-15305 and k-41884, by single genes without dominance effect. Potential allelism of the salt tolerance genes has been studied for the accessions with monogenically determined salt tolerance, and either identity or tight linkage of the genes determining salt tolerance of accessions k-15305 and k-41884 has been demonstrated. Provisional designations Tsa1, Tsa2, and Tsa3 are proposed for the genetic factors determining salt tolerance of accessions k-10930, k-17227, and k-15305, respectively.     

Chromosomal location of powdery mildew resistance genes and cytogenetic analysis of meiosis in common wheat cultivar Meri

Common wheat cv. Meri was crossed to a set of 21 Chinese Spring monosomic lines to characterize resistance to powdery mildew and to determine the chromosomal location of the gene(s). Monosomic F1 plants were allowed to self-pollinate and to produce F2 seeds. Seedlings of F2 and F3 plants and their parents were inoculated with isolates Ns 2 and 9 of Erysiphe graminis f. sp. tritici. Analysis of obtained data revealed that one major dominant gene conferring resistance is located on chromosome 1B of cv. Meri. The new gene is designated by symbol Pm28. On the basis of the trivalent configuration frequency (without univalent) at the 1st metaphase of meiosis it was found that two reciprocal translocations involving chromosomes 2A/5A and 5B/5D differentiate cv. Meri from cv. Chinese Spring. In the F1 monosomic hybrids, genes causing a decrease in pairing are found on chromosomes 4D and 6D, and genes enhancing pairing--on chromosomes 3A and 7B.