Società Italiana di Genetica Agraria
fondata nel 1954 da Carlo Jucci
Italian Society of Agricultural Genetics
founded by Carlo Jucci in 1954
Congressi SIGA
- Book of abstracts cover
- Scientific Programme
- Session I - Genomics and proteomics
- Session II - Breeding strategies
- Session III - Genetic control of reproduction
- Session IV - Genetics and breeding of stress resistance
- Session V - Working Groups
- Session VI - Environmental impact of GMOs and food safety
- Authors Index
- Keywords Index
Keywords Index
| 2n gametes |
3.7 |
| A | |
| ABA | S4c |
| abnormality | S3f |
| acclimation capacity | 4.11 |
| AFLP | S2b , S3h , 2.11 , 2.18 , 3.7 , 3.11 , 5.3 , 5.4 , 5.7 , 5.8 , 5.35 , 5.40 , 5.41 , 5.45 , 5.55 , 5.61 , 5.62 |
| alfalfa | S2g , 2.19 , 2.20 , 5.41 |
| Alfalfa Mosaic Virus (AMV) | 4.25 |
| allergy | 5.2 |
| allopolyploidy | 5.62 |
| ALS | 4.4 |
| analytical methods | 6.6 |
| aneuploidy | 2.10 |
| anther culture | 5.59 |
| anthocyanins | 5.58 |
| aphid | 4.25 |
| apomeiosis | S3h |
| apomixis | 3.6 , 3.8 |
| apospory | 3.6 |
| AP-PCR markers | 5.46 |
| apple | S2e , 5.57 |
| apricot | 5.57 |
| aquaporin | 5.19 |
| Arabidopsis thaliana | S4b , 1.10 , 3.2 , 4.5 , 4.47 |
| artichoke | 2.14 , 2.15 |
| ATHB-1 | S4a |
| attP | S6c |
| auxin |
5.20 |
| B | |
| BAC clones | 4.14 |
| BAC library | 1.8 , 1.13 , 1.12 , 1.19 |
| backcross | 4.24 |
| barley | S2c , S3b , S4c , 4.6 , 4.8 , 4.9 , 4.15 , 4.16 , 4.34 , 5.39 |
| BaYMV | S2c |
| biodiversity | 1.14 , 5.3 |
| biotechnology | 4.26 , 5.53 |
| Bipolaris oryzae | 4.35 |
| birdsfoot trefoil | 6.4 |
| Brachetto g.l. | 3.10 |
| Brassicaceae | S1b |
| breeding | S2f , 2.11 , 2.22 , 2.26 , 5.51 |
| brown spot | 4.35 |
| bulk segregant analysis | S2d |
| BYDV |
S2c |
| C | |
| caesium | 4.47 |
| callose | 4.12 |
| callus induction | 2.27 |
| Cannabis sativa L. | S3d |
| capsaicin | 5.47 |
| Capsicum L. | 5.47 |
| carotene | 5.24 , S2d |
| carotenoid | 5.24 |
| carotenoid pigments | 5.47 |
| catalase | 4.41 |
| cattle | 4.1 |
| cattle | S3f |
| cDNA | S3h , 4.15 |
| cDNA AFLP | S1d , S3d , 1.7 , 4.2 , 4.10 |
| cDNA cloning | 5.58 |
| cDNA subtraction | S1d |
| cell cycle synchronization | 2.5 |
| cereals | 6.6 |
| chamomile breeding | 5.6 |
| characterisation | 5.47 |
| Chardonnay | 3.10 |
| chickpea | 5.13 |
| chimeric virus particles | 6.1 |
| chlorophyll synthesis | 4.46 |
| chloroplast DNA | 2.25 |
| chloroplast transformation | 2.20 |
| chromosome | S3f |
| chromosome aberrations | 4.1 |
| chromosome characterisation | 5.12 |
| chromosome walking | 1.8 |
| Citrus | 5.59 |
| Citrus sinensis | 5.58 |
| clones | 5.55 |
| cluster analysis | 2.7 , 5.61 |
| co-expression | S6c |
| cold acclimation | 4.8 , 4.9 |
| cold stress | 4.6 , 4.7 |
| cold tolerance | S4b , 4.10 |
| colinearity | 1.10 |
| comparative mapping | 1.10 |
| Condensed tannins | S1d , 1.15 |
| coping strategy | S4d |
| copy number | 2.9 |
| COR genes | 4.6 |
| corn | 2.5 , 5.32 |
| Corylus avellana L. | 3.12 |
| co-segregation | S6c |
| co-transformation | S6c |
| Cow | 1.2 |
| cre/loxP | S6c |
| crop protection | 4.26 |
| cross-pollination | 6.5 |
| cultivar identification | 2.28 , 5.40 |
| cuticular wax | 5.34 |
| cybrids | S2f , 2.26 |
| cystein proteinase inhibitor | 4.45 |
| cytogenetics | 1.1 |
| cytoplasmic organelles | 2.12 |
| cytoskeleton | 3.3 , 5.37 |
| dairy parlour wastewaters |
6.8 |
| D | |
| DD | S3h |
| DDRT-PCR | S4c |
| defence genes | 4.22 , 4.26 , 4.28 , 4.31 |
| defoliation | 4.10 |
| dehydrin | 4.18 |
| dendritic cells | 6.1 |
| developmental mutants | 5.39 |
| DFR | 1.15 |
| differential display | 1.18 |
| differential expression | S1f |
| directional selection | 2.6 |
| distinctness testing | 2.21 |
| diversity | 2.11 , 5.10 |
| DNA | S2b |
| DNA fingerprinting | 3.8 |
| DNA horizontal transfer | S6e |
| DNA methylation | 4.17 |
| DNA polymorphisms | 2.21 |
| DNA uptake | S6e |
| domestic animals | S4d |
| downy mildew | 4.38 |
| drought | S4c |
| drought stress | 4.15 , 4.16 |
| dTph1 | 1.16 |
| durum wheat | S2d , 1.12 , 1.13 , 2.1 , 2.2 , 5.26 |
| dwarf |
5.21 |
| E | |
| ecotypes identification | 2.3 |
| ectomycorrhizae | 1.18 |
| einkorn | 5.24 |
| endosperm | 5.36 |
| enviroments | 3.11 |
| essentially derived varieties | 5.35 |
| ESTs | S3h , 4.14 |
| ethylene | S4a |
| Eustoma | 5.52 |
| exon-intron organization | 1.2 |
| expression pattern |
5.34 |
| F | |
| farming systems | 5.42 |
| fertility | 2.10 |
| fingerprinting | 2.2 |
| FISH | S3f , 5.63 |
| fission yeast | 3.9 |
| flavonoids | 5.58 |
| floral biology | 3.11 |
| flow cytometric analysis and sorting | 2.5 |
| flow cytometry | 2.26 |
| flower | 5.52 |
| flower development | S1f |
| flowering | 1.8 , 3.2 |
| flowering control | S1f |
| flowering time | 1.7 |
| fluorescence | 1.1 |
| forage perennial legumes | 5.42 |
| Fragaria vesca L. | 5.54 |
| free-hybrid | 2.19 |
| fruit set | S3g |
| functional genomics | 1.14 |
| functional markers | 5.37 |
| fungal pathogens | 4.26 , 4.31 |
| Fusarium sp. |
4.39 |
| G | |
| G1/S transition | 1.11 |
| gene expression | 1.6 , 1.11 , 4.10 |
| gene family | 4.28 |
| gene flow | 6.4 , 6.5 |
| gene isolation | 4.20 |
| gene promoter | 5.29 |
| gene pyramiding | S2c |
| gene regulation | 4.6 |
| gene structure | 5.29 |
| genetic control | 3.6 |
| genetic distance | 1.17 , 5.3 |
| genetic diversity | 1.20 , 2.2 , 2.7 , 5.14 |
| genetic engineering | S2g |
| genetic fingerprinting | 5.8 |
| genetic map | 1.1 , 2.1 |
| genetic relationships | 5.56 |
| genetic resources | S1b , 4.39 , 5.12 , 5.13 , 5.42 |
| genetic transformation | 4.22 , 4.31 , 4.40 |
| genetic variability | S2b , 2.21 , 5.61 |
| genetics | S4d |
| genome | 1.19 |
| genomic library | 5.26 |
| genomic structure | 5.34 |
| genotype characterisation | 2.18 |
| genotypes | 4.19 |
| genotyping | 5.56 |
| geranil geranil hydrogenase | 4.46 |
| germination | 4.10 |
| germplasm | 2.4 , 4.25 , 4.21 , 5.10 , 5.13 |
| germplasm collection | 5.47 |
| gibberellic acid | 5.21 |
| gibberellins | S3g |
| glossy | 5.34 |
| glutenin | 5.27 |
| glutenin polymer | 5.27 |
| glutenin subunits | 5.27 |
| glutenin subunits genes | 5.27 |
| GM feed | S6e |
| GMO | S6d , 5.35 |
| goat | 5.2 |
| grapevine | 3.10 |
| graphical genotyping | 2.2 |
| grass pea | 5.9 |
| green fluorescent protein | 5.52 |
| group 7 chromosomes | 4.30 |
| GUS | 5.20 |
| gymnosperms |
1.19 |
| H | |
| hairy roots | 2.17 |
| haploids | 2.11 , 5.59 |
| Hazelnut | 3.12 |
| HD-Zip transcription factor | S4a |
| heat shock proteins | 4.13 |
| heavy metals | 6.8 |
| Helicoverpa armigera | 4.45 |
| herbicides | 4.4 |
| heterologous hybridisation | 5.26 |
| hexaploid wheat | 5.29 |
| histone deacetylase | 1.6 |
| HIV-1 | 6.1 |
| HMW DNA | 1.12 |
| homeotic genes | 5.39 |
| homologous recombination | S2g |
| Hordeum vulgare | 1.14 , 4.14 , 5.37 |
| horizontal resistance | 4.36 |
| horse | 4.2 |
| HPLC | 4.11 |
| HPV16 | 6.3 |
| HR | 4.12 |
| Human Papilloma Virus (HPV) | 6.2 |
| hybridisations | 2.15 |
| Hypericum perforatum | 3.8 |
| hypersensitive response |
4.3 |
| I - K | |
| immunolocalization | 3.3 |
| in situ hybridization | 1.11 , 4.30 , 5.44 |
| in vitro culture | 2.6 |
| in vitro production | 5.22 |
| incompatibility | 3.12 |
| industrial processing | 6.7 |
| insect damage | 4.46 |
| insect resistance | 4.42 , 4.45 |
| interspecific crosses | 5.7 , 5.51 |
| interspecific hybrids | 2.13 |
| introgression | 5.7 |
| inverse PCR | 5.29 |
| in vitro culture shoot growth | 2.27 |
| isogenic lines | 1.7 |
| ISSR markers | 2.25 , 5.46 |
| Italian inbred lines | 2.7 |
| ITS | 2.3 |
| kinases |
3.3 |
| L | |
| lactoglobulin | 5.2 |
| landraces | 5.8 , 5.13 , 5.14 |
| Lathyrus spp. | 5.10 |
| lead | 5.23 |
| leaf stripe | 4.34 |
| lectin gene | 5.11 |
| Leguminosae | 5.44 |
| Lens culinaris | 5.12 |
| Lens ssp. | 5.11 |
| Leucine-rich repeat proteins | 4.28 |
| Limonium | 5.51 |
| linkage | 2.4 |
| linkage map | 5.62 |
| linkage mapping | 5.39 |
| lipoxygenase gene | 5.26 |
| local germoplasm | 5.32 |
| Lotus | S1d , 1.15 , 2.22 |
| low phytic acid mutant | 2.8 |
| LT50 | 4.11 |
| lucerne | 4.25 |
| lutein | 5.24 |
| Lycopersicon esculentum |
S3g |
| M | |
| M-AFLP | 5.45 |
| magnetic fields | 5.59 |
| maize | 1.7 , 1.8 , 2.8 , 4.10 , 5.34 |
| male fertility | 2.12 |
| male gametogenesis | S3b |
| male sterility | 2.15 |
| malsecco | 2.26 |
| Malus x domestica | S2e |
| Marker Assisted Selection (MAS) | S2c , 2.4 , 4.34 , 4.37 |
| mass spectroscopy | 4.11 |
| Medicago | 5.41 |
| Medicago sativa | 5.40 |
| Medicago sativa L. complex | 4.25 |
| Medicago scutellata | 4.42 |
| Medicago truncatula Gaertn. | 5.44 |
| medicinal plants | 5.6 |
| Mediterranean fruitfly | S6b , 3.1 |
| meiosis | 3.3 , 3.9 |
| melon | 4.21 |
| meristems | 3.2 |
| metal tolerance | 6.9 |
| microanalysis | 4.47 |
| microarray analysis | 4.15 |
| microfluorescence | 4.47 |
| micropropagation | 2.14 |
| microsatellites | S1e , 5.56 |
| microsatellites markers | S2d |
| microspore | S3b |
| modified AFLP | 2.26 |
| molecular genetics | S1b |
| molecular map | S2e |
| molecular marker assisted selection | 4.24 |
| molecular markers | 1.20 , 2.1 , 2.6 , 2.7 , 3.8 , 5.12 , 5.32 |
| Moraiolo | 5.60 , 5.61 |
| morpho-agronomic traits | 5.9 |
| morphology | 5.60 |
| Mps-one-binder (Mob) | S3h |
| MSAP | 4.17 |
| multivariate analyses | 5.9 |
| mutagenesis | 2.8 |
| mutant | 5.21 |
| mutants | 2.14 , 5.20 |
| mutation rates | S1e |
| Mutator element | 1.6 |
| myb factors |
S4b |
| N | |
| necrotic mutant | 4.12 |
| nested-PCR | 6.7 |
| nitric oxide | 4.3 |
| Non-invasive vibrating oxygen-selective probe | 2.25 |
| Northern analysis | S1f |
| Norway spruce | 1.19 , 1.20 , 5.63 |
| nuclease |
S3b |
| O | |
| ODAP | 5.10 |
| oil content | 5.6 |
| Olea europaea L. | 2.27 , 3.11 , 4.7 , 5.61 |
| olive | 4.40 |
| on farm conservation | 5.14 , 5.8 |
| opaque-2 | 5.33 |
| organogenesis | 2.17 |
| ornamental crops | 5.53 |
| orthology | 1.10 |
| Oryza sativa L. | 4.22 |
| osmotic stress | 4.20 |
| osmotin | 4.40 |
| Osteospermum | 2.18 , 5.52 |
| oxidative stress |
4.41 |
| P | |
| Papaver rhoeas | 4.4 |
| parthenocarpy | S3g |
| parthenogenesis | 3.6 |
| particle bombardment | 5.54 |
| pathogen infection | 4.41 |
| PC synthase | 6.9 |
| PCD | 4.12 |
| PCR | S6d , 2.21 , 2.22 , 6.6 |
| PDI | 5.29 |
| peach | 4.46 , 5.57 |
| pear | 5.57 |
| Pearl millet | 4.38 |
| Pennisetum glucu | 4.38 |
| Petunia hybrida | 1.16 , 3.9 |
| PGIP | 4.28 |
| phenotypic mass selection | 5.46 |
| phosphorylation | 5.33 |
| photoautotrophic cultures | 5.22 |
| Phragmites australis | 6.8 |
| phylogenesis | 2.22 |
| phylogenetic relationship | 2.28 |
| physiological background | 4.36 |
| phytochelatins | 6.9 |
| phytoremediation | 6.8 |
| Picea abies K. | S1e |
| Pisciottana | 2.28 |
| Pisum sativum L. | 4.17 |
| plant architecture | 2.17 |
| Plant chromosome and nuclei isolation | 2.5 |
| plant protection | S1b |
| plant-pathogen interaction | 4.3 |
| plastome | S2g |
| ploidy manipulations | 4.11 |
| Poa pratensis | 3.6 , 5.45 |
| pollen dispersal | 6.4 |
| polyamines | 3.10 , 4.5 |
| Polygalacturonase-inhibiting protein | 4.28 |
| polymorphism | 5.60 |
| polyphenol oxidase | 5.28 |
| population genetics | S1e |
| Posidonia oceanica | 5.19 |
| positional cloning | 1.8 |
| potato | 2.13 |
| potato cells | 4.20 |
| production | 5.60 |
| programmed cell death | S3b |
| promoter | 4.18 , 5.2 |
| promoter analysis | 4.9 |
| promoters | 4.22 |
| protein content | 5.10 , 5.28 |
| proteinase inhibitors | S1b , 4.42 |
| protoplast fusion | S2f |
| Prunus persica L. | 2.25 , 4.41 |
| PVX | 6.1 , 6.2 , 6.3 |
| Pyrenophora graminea | S2c |
| Pyricularia grisea |
4.35 |
| Q | |
| QTL analysis | 4.16 , 4.6 |
| QTL mapping | S2d |
| QTL markers | S2e |
| quality | 2.13 |
| quantitative expression | 1.15 |
| quantitative PCR |
2.9 |
| R | |
| random genetic drift | 2.6 |
| RAPD | 5.5 |
| RDA | 1.7 |
| rDNA | 5.44 |
| Real-Time PCR | 1.15 , 2.9 |
| red chicory | 5.46 |
| remating frequency | 3.1 |
| repetitive DNA | 5.63 |
| reporter genes | 5.20 |
| reproduction | S3f , 3.3 |
| resistance genes | 4.30 , 4.34 |
| resistance to TSWV | 4.24 |
| Retinoblastoma-related proteins | 1.11 |
| retrotransposons | 1.19 , 5.41 , 5.63 |
| reverse genetic | 1.16 |
| RFLP | 2.1 |
| ribosomal spacers | 2.22 |
| rice | S4b , 4.22 |
| rice blast | 4.35 |
| RIP | 4.22 , 4.31 |
| risk assessment | 6.5 |
| river buffalo | 1.1 |
| RNA | 4.2 |
| rol genes | 4.36 |
| rolB | 6.9 |
| rolD | 3.2 |
| root-rot | 4.39 |
| Rootstock | 2.25 |
| Rosa hybrida | 5.53 |
| Rpd3-type histone deacetylases | 1.11 |
| rRNA |
3.12 |
| S | |
| S. fragilis | 5.62 |
| S. tuberosum | 2.10 |
| Salix alba | 5.62 |
| salt stress | 4.19 , 4.21 |
| SAMPL | S2b , 5.41 |
| scab resistance | S2e |
| seed quality | 5.12 |
| seed storage protein | 5.11 |
| selection | 4.39 |
| sexual differentiation | S3d |
| sexual polyploidization | 3.7 |
| sheep | S2b , 1.2 , 5.1 |
| single nucleotide polymorphism | 4.38 |
| sister chromatid exchanges | 4.1 |
| snoRNA | 3.12 |
| SNPs | 1.20 |
| soil salinity | 5.42 |
| Solanum spp. | 2.11 , 2.12 |
| Solanum commersonii | 2.10 , 4.20 |
| Solanum melongena L. | 4.37 |
| somatic embryogenesis | 2.17 , 3.10 , 4.40 , 5.53 , 5.54 |
| somatic hybrids | S2f |
| SSR | 4.16 , 5.4 , 5.45 |
| SSR markers | 2.2 , 5.57 |
| Sterile Insect Technique | S6b , 3.1 |
| STMS | 5.4 |
| strawberry | 5.54 |
| stress | S4a , S4d , 4.5 |
| subcellular localization | 5.33 |
| sulfonylureas | 4.4 |
| sunflower | 4.18 , 5.21 , 5.22 |
| superoxide dismutase | 4.41 |
| suppression subtractive hybridisation | 4.7 |
| sweet orange flesh | 5.58 |
| synthetic variety |
2.19 |
| T - U | |
| T cell receptor | 1.2 , 5.1 |
| target genes | S4a |
| target-site | 4.4 |
| T-DNA tagging | 4.47 |
| tetraploid wheat | 5.28 |
| thermotolerance | 4.13 |
| tissue culture | 5.53 |
| TLC | 2.8 |
| tobacco | 4.19 , 5.5 , 5.23 |
| tocopherol biosynthesis | 5.22 |
| tolerance | 4.21 |
| tomato | S3g , 4.12 , 4.24 , 4.36 , 4.45 , 5.20 |
| traceability | S6d |
| transcription factor | S4c , 4.8 |
| transgene detection | 6.7 |
| transgenic lines | S6b |
| transgenic plants | S4b , 2.13 , 2.20 , 5.52 , 2.9 , 6.4 , 6.7 |
| transgenic tomato | 6.5 |
| transposon insertion mutant | 1.16 |
| TRDV genes | 5.1 |
| TRGC genes | 1.2 |
| Trifolium subterraneum L. | 4.39 |
| Triticum aestivum | 4.31 |
| Triticum dicoccum Schübler | 2.3 |
| truffles | 1.18 , 5.4 |
| tuber yield | 2.10 |
| tubulin | 2.21 , 5.37 |
| tubulins | S3h |
| uniparental expression |
5.36 |
| V | |
| vaccine | 6.1 , 6.2 , 6.3 |
| variability | 5.28 |
| variety identification | 1.17 |
| Verticillium tolerance | 4.37 |
| Vitis vinifera | 5.55 , 5.56 |
| Vrn-1 homologs |
4.14 |
| W | |
| water stress | 4.17 , 4.18 |
| water transport | 5.19 |
| welfare | S4d |
| wheat | S1f , 2.4 , 4.13 , 4.31 |
| wheat quality | 5.27 |
| wheat-alien transfers | 4.30 |
| wild sunflower |
5.7 |
| Z | |
| Zea mays | 1.6 , 1.10 , 1.11 , 2.6 , 2.7 , 5.35 |
| zearalenone | 4.1 |
| zein genes | 5.36 |