Mutation of a bHLH transcription factor allowed almond domestication.

Wild almond species accumulate the bitter and toxic cyanogenic diglucoside amygdalin. Almond domestication was enabled by the selection of genotypes harboring sweet kernels. We report the completion of the almond reference genome. Map-based cloning using an F1 population segregating for kernel taste led to the identification of a 46-kilobase gene cluster encoding five basic helix-loop-helix transcription factors, bHLH1 to bHLH5. Functional characterization demonstrated that bHLH2 controls transcription of the P450 monooxygenase-encoding genes PdCYP79D16 and PdCYP71AN24, which are involved in the amygdalin biosynthetic pathway. A nonsynonymous point mutation (Leu to Phe) in the dimerization domain of bHLH2 prevents transcription of the two cytochrome P450 genes, resulting in the sweet kernel trait.

First Report of Apricot latent virus and Plum bark necrosis stem pitting-associated virus in Apricot from Spain.

Representing 2% of world production, 20,000 ha of apricot (Prunus armeniaca L.), are cultivated in Spain, primarily in the southeast. A survey was conducted during the spring of 2008 in orchards in the region of Murcia to assess the incidence of several stone fruit viruses. Leaf and fruit samples from 160 trees from 40 orchards were collected randomly for reverse transcription (RT)-PCR analysis. Total RNA extracted (3) from leaves and fruits was tested by a multiplex one-step RT-PCR protocol with a mix of primers that detect eight distinct viruses (4). Amplicons of 250 bp expected for Plum bark necrosis stem pitting-associated virus (PBNSPaV), corresponding to part of the heat shock 70 protein gene, were obtained from four trees and amplicons of 700 bp expected for Apricot latent virus (ApLV), corresponding to part of the coat protein (CP) gene, were obtained from two trees. In all cases, amplicons were obtained using RNA extracted from leaf and fruit tissues. RT-PCR results were confirmed by uniplex RT-PCR with primers specific for each virus and dot-blot hybridization with virus-specific digoxygenin-labeled RNA probes (2). To further characterize the new viruses, we designed primers to amplify specifically the CP gene of ApLV (5'-CCCGACCATGGCTACAAGC-3' and 5'-TTGCCGTCCCGATTAGGTTG-3') and the minor CP gene of PBNSPaV (5'-GAACAAACTACAGCAGCACC-3' and 5'-CAAGGGTAGGACGGGTAACGC-3'). Amplicons of 1,500 and 950 bp corresponding to the ApLV and PBNSPaV CP genes, respectively, were purified from agarose gels and cloned in the pTZ57R plasmid (Fermentas, Burlington, Ontario, Canada). Blastp analysis of the full-length ApLV CP sequence from one infected tree (GenBank Accession No. GQ919051) revealed 86% amino acid (aa) similarity to the single full-length ApLV CP sequence available (No. AAC16234) and 79 and 66.9% similarity to Peach sooty ringspot virus (No. AAG48314) and Apple stem pitting virus (No. NP604468), respectively. Identity/similarity analysis of the full-length PBNSPaV minor CP genes using the Matrix Global Alignment Tool software, version 2.02 (1), revealed 98.8 to 99.6% aa similarity between the Spanish PBNSPaV isolates (Nos. GQ919047, GQ919048, GQ919049, and GQ919050) and 97.1 to 97.4% with the PBNSPaV isolate from the United States (No. EF546442). None of the six infected trees were associated with any particular field symptoms. Five infected trees were cv. Búlida and one was native cv. Murciana, which was infected with ApLV. All infected trees were located in geographically separated orchards. The incidence of ApLV and PBNSPaV was 1.25 and 2.5%, respectively. The low incidence of both viruses together with the scattered geographic distribution could be due to the recent introduction of virus-contaminated plants, although we cannot exclude that it is a consequence of a low dissemination rate. Even though no symptoms were observed, we cannot discard that the infection could affect fruit production or flowering or even cause a synergistic effect in mixed infection with other stone fruit viruses, a risk especially relevant considering the total area of cultivated apricot. To our knowledge, this is the first report of ApLV and PBNSPaV in Spain. References: (1) J. J. Campanella et al. BMC Bioinformatics 4:29, 2003. (2) M. C. Herranz et al. J. Virol. Methods 124:49, 2005. (3) D. J. Mackenzie et al. Plant Dis. 81:222, 1997. (4) J. A. Sánchez-Navarro et al. Eur. J. Plant Pathol. 111:77, 2005.

Inheritance of self-compatibility in almond: breeding strategies to assure self-compatibility in the progeny.

To assure self-compatibility in the progenies, three different crosses were conducted for the first time in an almond breeding programme: self-pollination (266 descendants from 30 families), crosses between parents sharing an S-allele (108 descendants from five families) and crosses with homozygous self-compatible parents (62 descendants from five families). Depending on the cross, self-compatibility in the progenies was determined by observing pollen tube growth (by means of fluorescence microscopy), stylar S-RNases analysis or allele-specific PCR. The results obtained fit with the accepted hypothesis of inheritance of self-compatibility and the three crossing strategies used ensured 100% of self-compatible descendants. These strategies increase the efficiency of the breeding programme and avoid the laborious task of evaluating this characteristic. From the breeding point of view, self-fertilisation and crosses between relatives tend to produce inbreeding. Furthermore, these methods reduce the possibilities of choosing the parental combination. The use of homozygous self-compatible parents does not have any of these disadvantages. As far as we know, this is the first time that allele-specific PCR has been used for early selection of self-compatible seedlings. The advantages and disadvantages of the three methodologies used to determine self-compatibility are discussed.

Relationship between cyanogenic compounds in kernels, leaves, and roots of sweet and bitter kernelled almonds.

The relationship between the levels of cyanogenic compounds (amygdalin and prunasin) in kernels, leaves, and roots of 5 sweet-, 5 slightly bitter-, and 5 bitter-kernelled almond trees was determined. Variability was observed among the genotypes for these compounds. Prunasin was found only in the vegetative part (roots and leaves) for all genotypes tested. Amygdalin was detected only in the kernels, mainly in bitter genotypes. In general, bitter-kernelled genotypes had higher levels of prunasin in their roots than nonbitter ones, but the correlation between cyanogenic compounds in the different parts of plants was not high. While prunasin seems to be present in most almond roots (with a variable concentration) only bitter-kernelled genotypes are able to transform it into amygdalin in the kernel. Breeding for prunasin-based resistance to the buprestid beetle Capnodis tenebrionis L. is discussed.

Response of antioxidative enzymes to plum pox virus in two apricot cultivars.

Recent evidence has indicated that activated oxygen species (AOS) may function as molecular signals in the induction of defence genes. In the present work, the response of antioxidative enzymes to the plum pox virus (PPV) was examined in two apricot (Prunus armeniaca L.) cultivars, which behaved differently against PPV infection. In the inoculated resistant cultivar (Goldrich), a decrease in catalase (CAT) as well as an increase in total superoxide dismutase (SOD) and dehydroascorbate reductase (DHAR) activities were observed. Ascorbate peroxidase (APX), glutathione reductase (GR) and monodehydroascorbate reductase (MDHAR) did not change significantly in relation to non-inoculated (control) plants. In the susceptible cultivar (Real Fino), inoculation with PPV brought about a decrease in CAT, SOD and GR, whereas a rise in APX, MDHAR and DHAR activities was found in comparison to non-inoculated (control) plants. Apricot leaves contain only CuZn-SOD isozymes, which responded differently to PPV depending on the cultivar. Goldrich leaves contained 6 SODs and both SOD 1 and SOD 2 increased in the inoculated plants. In leaves from Real Fino, 5 SODs were detected and only SOD 5 was increased in inoculated plants. The different behaviour of SODs (H2O2-generating enzymes) and APX (an H2O2-remover enzyme) in both cultivars suggests an important role for H2O2 in the response to PPV of the resistant cultivar, in which no change in APX activity was observed. This result also points to further studies in order to determine if an alternative H2O2-scavenging mechanism takes place in the resistant apricot cultivar exposed to PPV. On the other hand, the ability of the inoculated resistant cultivar to induce SOD 1 and SOD 2 as well as the important increase of DHAR seems to suggest a relationship between these activities and resistance to PPV. This is the first report about the effect of PPV infection on the antioxidative enzymes of apricot plants. It opens the way for the further studies, which are necessary for a better understanding of the role of antioxidative processes in viral infection by PPV in apricot plants.

Localization of Plum pox virus in stem and petiole tissues of apricot cultivars by immuno-tissue printing.

Localization of Plum pox virus (PPV) in stem and petiole tissues of four susceptible and four resistant apricot cultivars has been studied. Consecutive 1-mm spaced transverse sections were taken from the tissues and were printed onto nitrocellulose membrane in duplicate. For virus-specific detection, one series of prints was probed with an antibody to PPV coat and the density of stains was evaluated by light microscopy. Another series of prints was treated with a substrate but not with the antibody to reveal non-specific staining due to endogenous peroxidases. The virus was currently detected in all inoculated susceptible cultivars but only in one inoculated resistant cultivar (Harcot). In the stem tissues, the virus was localized in the pith and in the xylem. In the petiole tissues, it was localized in the epidermis and in cortical and medullae parenchyma. Non-specific staining was observed only in the stem sclerenchyma and in the petiole phloem.

Efficiency of inoculation of peach GF305 seedlings with Plum pox virus by different methods.

Peach GF305 is frequently used as rootstock in experiments to evaluate the resistance of different species of Prunus to Plum pox virus (PPV) because of its extreme susceptibility. However, transmission of PPV in Prunus species is sometimes problematic due to its low concentration or uneven distribution in these species. To determine the most effective way of transmitting the virus, different infection methods (by aphids, grafting, mechanical infection and injection) were tested using Dideron PPV isolates. The most effective method was the grafting of herbaceous material with inoculum derived from similar herbaceous material. Infection by aphids was more laborious and less effective than grafting, showing many disadvantages. Neither mechanical infection nor injection transmitted the virus.

Genotype x environment interaction in QTL analysis of an intervarietal almond cross by means of genetic markers.

Besides QTL location and the estimation of gene effects, QTL analysis based on genetic markers could be used to comprehensively investigate quantitative trait-related phenomena such as pleiotropy, gene interactions, heterosis, and genotype-by-environment interaction (G x E). Given that the G x E interaction is of great relevance in tree improvement, the objective of the research presented here was to study the effect of years on QTL detection for 15 quantitative traits by means of isozymatic markers in a large progeny group of an intervarietal cross of almond. At least 17 putative QTLs were detected, 3 of which had alleles with opposite effects to those predicted from the parental genotypes. Only 3 QTLs behaved homogeneously over the years. Three possible causes are discussed in relation to this lack of stability: the power of the test statistic being used, the low contribution of the QTL to the genetic variation of the trait, and a differential gene expression dependent on the year (G x E). Most cases showing lack of stability involved traits whose heritability estimates change drastically from year to year and/or whose correlation coefficients between years are low, suggesting the presence of G x E as the most likely cause. A marker-assisted selection scheme to improve late flowering and short flowering duration is suggested for an early and wide screening of the progeny.