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 |