FR2631205A1 - Process for testing maize seeds for varietal purety - Google Patents

Abstract

The present invention relates to a process and to a device which makes it possible to test seeds for varietal purety, consisting in germinating in an artificial substrate and under specified surrounding conditions and in comparing the phenotypic features of the plantlet with controls. According to the process, the plantlet is brought to the two-leaf stage 7, 8 with a coleoptile 5 with a length of 4 cm from the substrate, by germinating in a horizontal tub at a relative humidity of 90 % with a photoperiod of an exact duration after a period of darkness and at a controlled temperature. Use for testing maize seeds for varietal purety.

Description

The present invention relates to a method of con
trunk of seed purity, especially
of but. The invention furthermore covers a device
putting the implementation of the method above.

We know that at the moment seeds, and more
especially maize seeds, are mainly
made from carefully selected hybrid seeds
born and obtained by crossing from broodstock them
even selected. In the case of maize, we also know
that the plant can give a product resulting from a car
fertilization if the operation known per se of castration does not
not been totally successful. As a result, one lot of
seed can give rise, in the field, to a crop comprising
significant percentages of so-called aberrant products
and self-fertilization products, which hurts the homoge
origin of the said harvest and the quality of the products
wait for it.

 Field control of the purity of a seed lot requires a delay of one year after the date of harvest.

 We talk about control a posteriori, meaning after marketing, which is unfortunate.

 An attempt was made to check seed purity more rapidly in the laboratory by examining the characteristics of a sprouted seedling. We have for example. proposed a procedure to record the size and some characteristics of the first leaf after definite durations, fixed at 14 and 21 days from sowing. Such a method, however, does not give convincing and reliable results on the three-way and double hybrids, besides it does not make it possible to make a clear distinction between the aberrant and self-fertilization products.

 The present invention aims to remedy the above drawbacks, by providing a laboratory-based varietal purity control method based, on the one hand, on the study of new phenotypic characteristics of the seedling and, on the other hand, on the conditions and the material for obtaining said seedling by germination.

 According to the invention, a germination of artificial substrate is carried out under determined conditions of humidity, temperature and illumination, and the phenotypic characteristics of the germinated seedling relative to the controls are studied. bringing said seedling to the two-leaf stage with a 4 cm long coleoptile out of the substrate, by germination in a horizontal bin at a relative humidity of 90%, with a photo-period of 14 h / day and 10 h / night at a given intensity after a period of darkness, at a controlled temperature of 15 C + 1 ° C for early material and 18 C + 1 ° C for late material.

 According to another characteristic, a period of darkness of 12 to 14 days after sowing is maintained, followed by said photo-period at an intensity of illumination -2 -1 of 150 to 300 te ms, E representing the einstein, unit photochemical.

Other features and advantages of the invention will become more apparent from the following description, given with reference to the accompanying drawings in which:
Figure 1 shows a schematic view of a two-leaf stage seedling and its phenotypic characteristics useful according to the invention; and
FIG. 2 represents a schematic sectional view of an individual germination tank.
As mentioned above, a batch of seeds is brought by controlled germination at the two-leaf stage. Referring to FIG. 1, the obtained seedling comprises a radicle 1, caryopsis 2, mesocotyl 3 and anchor plate 4 for its underground part, then the coleoptile 5, the sheath 6 of the first sheet 7 and the second sheet 8. The first sheet itself comprises a blade 9, optionally bordered by a border 10 and an end 11. All the elements ci above are part of the phenotypic characters observed for the determination of varietal purity compared to known controls, as well as the size 12 of the seedling from the anchor plate 4 and the size difference 13 between the ends of the seedling. the first sheet 7 and the second sheet 8.

Field varietal purity testing is known to focus on the color of the stalk, the color of the kernels, and the shape, toothed or horny, of the stalk. The Applicant has therefore determined
on strictly selected pure lots of broodstock, hybrids, prepared aberrants and inbreeding products, the significant phenotypic characters to be found on the examined seedlings.

As phenotypic characters to be observed we can quote
seedling size compared to controls
(variety and self-fertilization)
growth of the seedling: angle of opening of the first leaf with respect to the second leaf (upright, semi-erect, drooping).

morphological characteristics of the first leaf
- size L - length Ratio L l - width
- blade shape (pointed end, oblong
or spatulate)
- color of the blade (intensity of pigmentation)
- folding - nervation
- absence or presence of edging
h.author of the first sheet in relation to the second sheet
- superior
- equivalent
- lower
sheath of the first leaf: shape, length, pigmentation.

 . coleoptile: shape, length, end, color.

. anchor tray: pigmentation
. mesocotyl: length, pigmentation
Tables I to III below give, by way of example, the phenotypic characteristics of certain varieties of maize, making it possible to establish for each a data sheet.

Table I: type F7 line

<tb><SEP> LINE <SEP> ABERRANTS
<tb>. <SEP> small <SEP> size <SEP> (control <SEP> pure) <SEP>. <SEP> sizes <SEP> greater <SEP> than
<tb><SEP> witness
<tb> port <SEP> trained <SEP>. <SEP> port <SEP> set <SEP> to <SEP> falling back
<tb>. <SEP> first <SEP> sheet <SEP>: <SEP> long, <SEP>. <SEP> first <SEP> sheet <SEP> more
<tb><SEP> narrow <SEP> slender, <SEP> pointed <SEP> wide, <SEP> very <SEP> long,
<tb><SEP> pointed <SEP> to <SEP> spatulas
<tb>. <SEP> color <SEP> 1st <SEP> sheet <SEP>: <SEP>. <SEP> color <SEP> 1st <SEP> sheet
<tb><SEP> dark green <SEP>"bright-glossy"<SEP> green <SEP> pale <SEP> to <SEP> dark green
<tb>. <SEP> Edited <SEP>: <SEP> absent <SEP>. <SEP> border <SEP> absent <SEP> or <SEP> present
<tb><SEP> (intensity)
<tb>. <SEP> Size <SEP> 1st <SEP> sheet <SEP> by <SEP>. <SEP> size <SEP><SEP> sheet <SEP> by
<tb><SEP> report <SEP> to <SEP> 2nd <SEP> sheet <SEP>: <SEP> report <SEP> to <SEP> 2nd <SEP> sheet
<tb><SEP> upper <SEP> equals <SEP> to <SEP> lower
<tb>. <SEP> sheath <SEP>: <SEP> green <SEP> uniform <SEP>. <SEP> sheath <SEP>: <SEP> green <SEP> to <SEP> dark green
<tb>. <SEP> coleoptile <SEP>: <SEP> brown-rosy <SEP>. <SEP> coleoptile <SEP> dark green <SEP> to
<tb><SEP> red-purple
<tb>. <SEP> mesocotyl <SEP>: <SEP> white <SEP>. <SEP> mesocotyle <SEP>: <SEP> white <SEP> to
<tb><SEP> purple <SEP> dark
<Tb>
The following are the essential elements of the maize varieties referred to in Table I above and Tables II to IV given later in this paper, namely:
Variety denomination Breeder Nature of the hybrid
F7 INFRA Lineage
LG 26 Monsoon LG Hybrid Services simple
LG 9 Circe LG Dual Hybrid Services
LG ll Limac Limagrain Hybrid three way
LG 22.50 Argos LG Services Hybrid three-way Table II: Hybrid single LG 26

<SEP> HYBRID <SEP> ABERRANTS
<tb>. <SEP> size <SEP> very <SE> large <SEP> by <SEP>. <SEP> very <SEP> small / line <SEP>. <SEP> size <SEP> variable <SEP> (large <SEP> to
<tb><SEP> report <SEP> to <SEP> witness <SEP> pure <SEP> very <SEP> large)
<tb>. <SEP> port <SEP> trained <SEP>. <SEP> port <SEP> semi-erect <SEP>. <SEP> port <SEP> variable
<tb>. <SEP><SEP> leaf <SEP>: <SEP> oblong <SEP>. <SEP><SEP> leaf <SEP>: <SEP> short <SEP>. <SEP><SEP> leaf <SEP>: <SEP> oblong <SEP> to
<tb><SEP> long <SEP> slightly <SEP> hemmed, <SEP> no <SEP> spatulas
<tb><SEP> symmetric
<tb>. <SEP> color <SEP> of <SEP><SEP> sheet <SEP>: <SEP>. <SEP> color <SEP>;<SEP> green-yellowish <SEP>. <SEP><SEP> leaf <SEP>: <SEP> dark green
<tb><SEP> green <SEP> (often <SEP> decol, <SEP> or <SEP> ation)
<tb>. <SEP> border <SEP>: <SEP> white <SEP>. <SEP> border <SEP>: <SEP> enough <SEP> pronounced <SEP>. <SEP> bound <SEP>: <SEP> purple <SEP> dark
<tb>. <SEP> size <SEP><SEP> sheet / <SEP>. <SEP> the <SEP> sheet / 2nd <SEP><SEP> sheet. <SEP> 1st <SEP> sheet / 2nd <SEP> sheet
<tb><SEP> 2nd <SEP> sheet <SEP>: <SEP> lower <SEP> lower <SEP> variable
<tb><SEP> or <SEP> equals
<tb>. <SEP> sheath <SEP><SEP> leaf <SEP>: <SEP> green, <SEP>. <SEP> sheath <SEP> purple-brown, <SEP> short <SEP>. <SEP> sheath <SEP> red <SEP> to <SEP> dark purple
<tb><SEP> long.
<Tb>

. <SEP> coleoptile <SEP>: <SEP> purplish <SEP> to <SEP> the <SEP>. <SEP> coleoptile <SEP>: <SEP> green <SEP>. <SEP> coleoptile <SEP>: <SEP> variable
<tb><SEP> base
<tb>. <SEP> mesocotyl <SEP>: <SEP> white <SEP>. <SEP> mesocotyl <SEP>: <SEP> white <SEP>. <SEP> mesocotyl <SEP>: <SEP> purple
<tb> TABLE III: LG Double Hybrid 9

<SEP> AUTO-FECONDATION <SEP> ABERRANTS
<tb>. <SEP> size <SEP> large <SEP> (control <SEP> pure) <SEP>. <SEP> size <SEP> small <SEP> (witness) <SEP>. <SEP> size <SEP> variable
<tb>. <SEP> port <SEP> half-erect <SEP>. <SEP> port <SEP> set <SEP>. <SEP> port <SEP> variable
<tb>. <SEP><SEP> sheet <SEP>: <SEP> long, <SEP>. <SEP><SEP> leaf <SEP>: <SEP> close, <SEP>. <SEP><SEP> leaf <SEP>: <SEP> close
<tb><SEP> wide, <SEP> oblong, <SEP> to <SEP> edges <SEP> pointed <SEP>, and <SEP> long <SEP> to <SEP> wide,
<tb><SEP> returned <SEP> spatulate
<tb>. <SEP> color <SEP> sheet <SEP>: <SEP> green <SEP> to <SEP>. <SEP> color <SEP>: <SEP> green <SEP> more <SEP> dark <SEP>. <SEP> same <SEP> variety
<tb><SEP> veins <SEP> dark purple <SEP> to <SEP> veins <SEP> violets
<tb>. <SEP> border <SEP>: <SEP> white <SEP> to <SEP> purple <SEP>. <SEP> border <SEP>: <SEP> purple <SEP> dark <SEP>. <SEP> border <SEP>: <SEP> variable
<tb>. <SEP> size <SEP> l <SEP> sheet / 2nd <SEP>. <SEP> size <SEP> l <SEP> sheet / 2nd <SEP>. <SEP> size <SEP>: <SEP> variable
<tb><SEP> Sheet <SEP> Bottom <SEP> Sheet <SEP> Upper
<tb>. <SEP> sheath <SEP><SEP> leaf <SEP>: <SEP> green <SEP>. <SEP> sheath <SEP>: <SEP> light purple <SEP>. <SEP> sheath <SEP>: <SEP> green <SEP> to
<tb><SEP> to <SEP> purple <SEP> dark <SEP> purple <SEP> dark
<tb>. <SEP> coleoptile <SEP>: <SEP> clear <SEP> to <SEP>. <SEP> coleoptile <SEP>;<SEP> green <SEP> to <SEP> pink- <SEP>. <SEP> coleoptile <SEP>: <SEP> clear <SEP> to
<tb><SEP> purple <SEP> dark <SEP> dark <SEP> (never <SEP> purple) <SEP> purple <SEP> dark
<tb>. <SEP> mesocotyl <SEP>: <SEP> purple <SEP> dark <SEP>. <SEP> mesocotyl <SEP>: <SEP> white <SEP>. <SEP> mesocotyl <SEP>: <SEP> white
<tb> The family of aberrants presents a great variability of shapes and colors, by their origins.

 Of course, the interpretation of the seedlings was controlled in the field by transplanting said seedlings and observation of the plants and. ears obtained. Transplanting is done at the two-leaf stage within 24 hours. Table IV below shows, by way of example, the results of the correlations obtained between the laboratory interpretation and the field control mode.

Table IV

<tb><SEP> Varieties <SEP>% AUTO-FECONDATION <SEP>% ABERRANT
<tb><SEP> I <SEP> LABORATORY <SEP> FIELD <SEP> LABORATORY <SEP> FIELD
<tb> LG <SEP> 9 <SEP> - <SEP> HARVESTING <SEP> 1984
<tb> Code <SEP> Sample. <SEP> n <SEP> 12 <SEP> 2.8 <SEP> 1.9 <SEP> 2.0 <SEP> 0.8
<tb><SEP> 31 <SEP> 2.5 <SEP> 1.7 <SEP> 2.0 <SEP> 0.6
<tb><SEP> 33 <SEP>, <SEP> 3.0 <SEP> 1.6 <SEP> 0.7 <SEP> 0.0
<tb><SEP> 40 <SEP> 0.5 <SEP> 0.0 <SEP> 0.5 <SEP> 0.5
<tb><SEP> 44 <SEP> 0.5 <SEP> 0.5 <SEP> 0.2 <SEP> 0.0
<tb><SEP> 47 <SEP> 1.0 <SEP> 1.1 <SEP> 1.3 <SEP> 1.1
<tb><SEP> 25 <SEP> 2,3 <SEP> 1,5 <SEP> 0,2 <SEP> 0,5
<tb><SEP> 30 <SEP> 1.8 <SEP> 0.0 <SEP> 1.0 <SEP> 0.0
<tb> LG <SEP> 1l <SEP> - <SEP> HARVESTING <SEP> 1985 <SEP>
<tb> Code <SEP> Sample <SEP> n <SEP> 6a <SEP> 13.4 <SEP> 10.1 <SEP> 1.0 <SEP> 0.1
<tb><SEP> 65 <SEP> i <SEP> 11.6 <SEP> 9.2 <SEP> 2.0 <SEP> 0.0
<tb><SEP> 73 <SEP> i <SEP> 4.1 <SEP> 3.6 <SEP> 2.0 <SEP> 1,2
<tb><SEP> 77 <SEP> 1 <SEP> 6.3 <SEP> 3.5 <SEP> - <SEP> 1.8 <SEP> 0.6
<tb><SEP> 80 <SEP> 3.8 <SEP> 3.8 <SEP> 2.3 <SEP> 1.5
<tb><SEP> 82 <SEP>, <SEP> 6.8 <SEP> 4.2 <SEP> 2.3 <SEP> 0.6
<tb><SEP> 93 <SEP> 2.5 <SEP> 1.6 <SEP> 0.2 <SEP> 0.5
<tb><SEP> 99 <SEP> 2.0 <SEP> 0.9 <SEP> 0.5 <SEP> 0.0
<tb><SEP> 107 <SEP> 8.7 <SEP> 7.6 <SEP> - <SEP> 2.5 <SEP> 1.8
<tb> LG <SEP> 22.50 <SEP>
<tb> HARVESTING <SEP> 1985 <SEP> i
<tb> Code <SEP> Sample. <SEP> No 836 <SEP> 3.1 <SEP> 1.1 <SEP> 0.0 <SEP> 0.0
<tb><SEP> 839 <SEP> 1 <SEP> 0.8 <SEP> 1.0 <SEP> 0.5 <SEP> 0.3
<tb><SEP> 844 <SEP> 3.0 <SEP> - <SEP> 0.6 <SEP> 0.5 <SEP> 0.0
<tb><SEP> 856 <SEP> 1.5 <SEP> 0.3 <SEP> 0.0 <SEP> 0.0
<tb><SEP> 858 <SEP> 1.5 <SEP> 1.1 <SEP> 0.5 <SEP> 0.5 <SEP>
<tb><SEP> 865 <SEP> - <SEP> 2.5 <SEP> 0.5 <SEP> 0.5 <SEP> 1.0
<Tb>
Considering the errors (sterile plants # 1% and aberrant not visible in ears) I%), transplanting results, the differences between the percentages of the two modes of control are not significant.

 For the implementation of the method according to the invention, it should be noted that the conditions of germination being very strict, the device, simple in itself, meets the characteristics that will now be detailed.

Referring to FIG. 2, an individual germination tank 14, of plastic material, has a capacity of 12 liters and is filled with a substrate consisting of Vermiculite of the "Vermex" type, M-caliber, density of 80 kg / m3. The bins are stacked by means of risers and placed on trolleys with six floors in a lit and air-conditioned enclosure. The seeds 15 are arranged at a rate of 200 per tray in the middle of the substrate 16, itself consisting of two layers 17 of equal thickness, preferably 2 cm. It is very important that the tray is arranged with horizontality control in order to avoid any heterogeneity in the size of the growing seedlings. In addition, the substrate is hydrolyzed by watering under the following conditions:
- for early material, at 15 "C: 2.6 liters of water for 8 1 of substrate, ie 0.8 1 / tank on the 7th day and, depending on the type of hybrid, 0.8 1 / tank at the 14th day
- for late material and lines in general, at 18 C: 2.8 1 of water for 8 1 of substrate with watering above.

 With regard to the temperature conditions, the Applicant has found, after numerous germination rate measurements, that a temperature of 15 ° C + 1 ° C is the most favorable for the development of seedlings of early varieties, a temperature of 180C + 1OC is better suited for late varieties.

Moreover, the Applicant has found that the duration of stay in the dark is determined as a function, on the one hand, of the growth rate differences between spawners and hybrids and, on the other hand, of the lengthening of the mesocotyl when this criterion favors interpretation.
This duration is practically fixed at 12-14 days. The date of passage between the darkness and the photo-period further determines the growth of the seedling, said photo-period to last 7 to 9 days at a rate of 10 hours of darkness and 14 hours of day at 150-300> 1E m-1 to ensure in particular sufficient foliar pigmentation, a rotation of 1800 bins being performed every 48 hours for reasons of homogeneity.

 it is understood that the present invention has been described and shown for explanatory purposes but not limiting and that we can make any useful changes, especially in the field of technical equivalents, without departing from its scope.

Claims (5)

 1. A method for controlling the varietal purity of seeds, in particular of maize, in which germination is carried out in an artificial substrate under conditions of determined humidity, temperature and illumination, and the phenotypic characteristics of the seedling are observed germination result relative to controls, characterized in that said seedling is brought to the two-leaf stage (7, 8) with a coleoptile (5) 4 cm long outside the substrate, by germination into horizontal tank (14) at a relative humidity of 90%, with photo-period of 14 h / day and 10 h / night at a given intensity after a period of darkness, at a regulated temperature of 15 ° C + 1 OC for the Early material and 18 "C + 1" C for late material.  2. Method according to claim 1, characterized in that the period of darkness is 12 to 14 days after sowing, the photo-period is 7 to 9 days and it is carried out at a light intensity. from 150 to 300 pE msi  3. Method according to one of claims 1 or 2, characterized in that one observes the following phenotypic characters: size (12) and the port of the seedling; leaf, shape, color of the first leaf (7); color of blade (9), fold, venation, border (10): height of first leaf relative to second leaf (8); sheath (6) of the first leaf, coleoptile (5); pigmentation of the anchor plate (4); length and pigmentation of the mesocotyl (3).  4. Method according to any one of claims 1 to 3, characterized in that the humidification of the substrate is carried out by watering at a rate of 2.6 1 of water per 8 1 of substrate for the material to early to 15 "C and 2.8 1 water per 8 1 of substrate for late material at 18" C.  5. Device for carrying out the method according to any one of claims 1 to 4, wherein the bins are arranged in an air-conditioned chamber, characterized in that each individual tray is arranged with horizontality control and filled with two layers (17) of a density substrate of 80 kg / m3, each bin containing 200 seeds (15) disposed between the two substrate layers.