Maize Genetics
Cooperation Newsletter vol 86 2012
CRA-MAC
Unit�
di Ricerca per la Maiscoltura
Via Stezzano 24, 24126 Bergamo (Italy)
Screening of Italian
maize inbred lines for nutritional quality, resistance to Fusarium verticillioides and differential gene expression in
resistant and susceptible genotypes *
Balconi, C, Hartings, H, Locatelli, S, Lanzanova, C, Panza, L, Torri, A, Alfieri, M, Berardo, N, Redaelli R
The introduction of hybrids into cultivation
brought up a significant increase in maize (Zea mays L.) grain yield and a better resistance to pathogens. On the
other hand, the possibility to help maintaining a good health
through a convenient diet have recently focused the interest in food
plants on the nutritional quality issue. The worldwide maize (Zea mays L.) germplasm
has been shown to possess a large genetic variability for the main components
of the grain. In particular, in Italy the availability of a large number of
populations and ecotypes represents an interesting starting point for the
identification of genotypes with good nutritional value and safety
characteristics (Berardo et al., J. Agric. Food Chem. 57: 2378-2384, 2009). Mycotoxin contamination in maize grain is a global threat
to both safety of human food and animal feed (Balconi
et al., World Mycotoxin Journal 3: 239-250, 2010;
Berardo et al., Food Additives and Contaminants:
Part B., 4: 116–124 2011). With the aim to find new sources of genetic
variability to improve the nutritional quality of maize hybrids and their
resistance to pathogens, a set of 35 traditional Italian inbred lines and six
public inbred lines (TABLE 1) was
evaluated in 2009 and 2010 in Bergamo (Northern Italy). A preliminary survey
was realized to test their response to the fungal pathogen Fusarium verticillioides, the causal agent of ear rot in most
maize-growing areas of Southern Europe. This
test implied: i) artificial inoculation of the ears
in field trials at 15 DAP (Days After Pollination) through the KIA (Kernel
Inoculation Assay) with a spore
suspension obtained from a mix of two toxigenic F. verticillioides strains isolated in Northern Italy; ii) visual rating of the infected
ears; iii) evaluation of the internal infection of the kernels; iv)
quantification (ELISA) of the mycotoxins (fumonisins) present in the grain. Controls were not inoculated
or inoculated with sterile H2O ears. Most of the inbred lines
(around 60%) both in 2009 and in 2010 showed, after
artificial inoculation, a low susceptibility to F. verticillioides, as deduced by visual rating evaluation. Both
during 2009 and 2010, artificial inoculation induced an evident increase in
fumonisin content. Large variability was observed between the genotypes. During
both years, around 15% of the tested inbred lines showed fumonisin content � 105
�g/kg after artificial inoculation; the other genotypes were almost equally distributed
in two groups depending on fumonisin content, respectively: � 104 �g/kg
and 104 � 105 �g/kg.
The inbred lines were also characterized by NIRS in terms of grain chemical composition (protein,
lipid and starch content). Crude protein and lipid contents, expressed on a dry
matter basis, were determined during both years on ears harvested after
different treatments. Inoculation with F.
verticillioides in 2009 appeared to slightly reduce the nutritional
compounds as compared to the control inoculations, whereas in 2010 the lowest
content of protein and lipid was found in the not inoculated ears.
In order to address the study of differential
gene expression in resistant and susceptible genotypes, two of the inbred lines
under study were selected: i) Lo 186, exhibiting
abundant mycelium growth and high level of fumonisins; ii) Lo 435 with a far more resistant phenotype and low
fumonisin content. Material was collected at two time points after inoculation;
total RNA was then isolated from each of the collected samples in order to prepare hybridization probes, which were subsequently used to
hybridize an Affymetrix maize array. Gene expression data analyses
were conducted in R language using the Limma package
from Bioconductor, comparing expression profiles of sterile
H2O-inoculated (control) and F.
verticillioides-inoculated samples. Upon comparison, around 500 genes
(P-value � 0.05) identified in Lo186 kernels after fungal inoculation were
differentially expressed. The classification in GO (Gene Ontology) functional
categories, showed their relative involvement mainly in i)
the response to biotic stimuli (for example mechanisms related to response to
fungus); ii) anatomical development processes.
In summary, results from the research
indicated that i) most of the
inbred lines both in 2009 and in 2010 showed a low-medium susceptibility to F.
verticillioides, as deduced by visual rating evaluation; ii) during both
years, around 15% of the tested inbred lines showed a fumonisin content � 105
�g/kg after artificial inoculation; the other genotypes could be almost equally
partitioned into two groups depending on fumonisin content; iii) plant defence
against F. verticillioides infection involved the expression change of
several genes; the knowledge of their association with main functional pathways
might disclose important information regarding those molecular processes active
during fungal infection.
*The
research recognises the financial support of the Research Programs RGV-FAO; ALISAL
and MICOPRINCEM , Italian Ministry of Agricultural
Food and Forestry Policies-MiPAAF.
TABLE
1-Maize genotypes under study |
|||
|
Italian
inbred lines |
Source |
Italian
inbred lines |
Source |
|
Lo 002 |
Nostrano dell'Isola |
Lo 491 |
Nostrano dell'Isola Finardi |
|
Lo 003 |
Nostrano dell'Isola |
Lo 514 |
Dente di cavallo |
|
Lo 005 |
Nostrano dell'Isola |
Lo 520 |
ICAR 54 |
|
Lo 017 |
Nostrano dell'Isola |
Lo 589 |
Nostrano dell'Isola |
|
Lo 018 |
Nostrano dell'Isola |
Lo 241 |
Lo3 x Lo38 |
|
Lo 020 |
Nostrano dell'Isola |
Lo 295 |
70 x 110 |
|
Lo 021 |
Nostrano dell'Isola |
Lo 352 |
Lo32xLo18 |
|
Lo 033 |
Isola basso |
Lo 446 |
Lo80 x Lo71 |
|
Lo 043 |
Scagliolo |
Lo 452 |
Lo5^2 x Lo19 |
|
Lo 051 |
Bianco Oderzo |
Lo 457 |
Lo43 x Lo58 |
|
Lo 058cmsC |
Marano |
Lo 1264 |
P3394 (Cecilia) |
|
Lo 067 |
Scagliolino G.V |
Lo 577 |
N.I. maranizzato |
|
Lo 093 |
Scagliolino G.V. precoce |
Lo 578 |
N.I. maranizzato |
|
Lo 186 |
Marano x Isola basso |
|
|
|
Lo 249 |
Scagliolo Marne |
Public inbred lines |
|
|
Lo 309 |
King Ko (Foggia) |
A632 |
|
|
Lo 387 |
Cinquantino San Fermo |
B73 |
|
|
Lo 404 |
Sacra Famiglia 43 |
DSP1771 |
|
|
Lo 434 |
Cinquantino Bianchi |
F2 |
|
|
Lo 435 |
Cinquantino Bianchi |
MBS847 |
|
|
Lo 441 |
Scagliolo Marne |
W117 |
|
|
Lo 465 |
Nostrano dell'Isola Finardi |
|
|
Please Note: Notes submitted to the Maize Genetics
Cooperation Newsletter may be cited only with consent of authors