专利汇可以提供Method of producing hybrid allium plant专利检索,专利查询,专利分析的服务。并且The present invention provides a method of producing a hybrid Allium plant comprising the steps of: preparing two different protoplast donors from two different Allium plants, isolating protoplasts from the donors, subjecting the protoplasts to cell fusion, and thereafter culturing fused cells. The method can be used even if one of the starting Allium plants has a vegetative propagation nature. The invention also provides a hybrid Allium plant produced by this method.,下面是Method of producing hybrid allium plant专利的具体信息内容。
This invention relates generally to hybridization of plants for improvement of breed. More particularly, the invention relates to hybrid plants belonging to "Allium" which are produced by cell fusion. The invention also concerns a method of producing such hybrid plants starting from cell fusion of protoplasts.
Generally, the Allium plants are classified into two different groups which include the so-called seed breeding type and the vegetative propagation type. The Allium plants belonging to the seed breeding type reproduce through sexual crossing, and include onion (Allium cepa) and Welsh onion for example. The vegetatively propagating Allium plants reproduce by the intermediary of bulbs, and include garlic (Allium sativum) and scallion (Allium ascalonicum) for example.
The two types of Allium plants are known to exhibit drastically different characters. Therefore, it is greatly beneficial to introduce the inheritable characters of one type of Allium plants into the other type Allium plants. Further, in view of breeding improvement, such character introduction should be preferably conducted between plants of the same type, either the seed breeding type or the vegetative propagation type, as well as between variant plants of the same species.
A typical method for inter-plant character introduction is the cross-fertilization. However, this known method is disadvantageous in that it is only applicable to closely similar plants in addition to requiring much time and labor for crossing or breeding procedures. More significantly, it is impossible to utilize the cross-fertilization in plants of the vegetative propagation nature.
It is, therefore, an object of the present invention to provide a hybridizing technique for the Allium plants which can be applied to various combinations of Allium plants for character introduction or mixing particularly with respect to Allium plants of the vegetative propagation nature.
Another object of the present invention is to provide a hybrid of the Allium plants.
To fulfill these objects, the present invention provides a method of producing a hybrid Allium plant wherein protoplasts obtained from two different Allium plants are subjected to cell fusion, and the obtained hybrid cells are thereafter cultured to complete plants.
Obviously, the use of cell fusion makes the method of the present invention applicable to any combination of Allium plants. Particularly, the method is advantageous in that it may be used even when one of the starting plants is of the vegetative propagation nature, as opposed to the conventional cross-fertilization method which is limited in applicability to plants of the seed breeding nature. Further, the method may be applied to a combination of different variants of the same species.
Another advantage of the present invention is that the method is free of seasonal limitations, and requires less time and labor than the conventional cross-fertilization method.
As a result of the present invention, it is possible to produce a hybrid Allium plant which has the respective characters of two different starting plants. More specifically, the following results may be obtained.
The present invention will now be described further, by way of example only, with reference to the accompanying drawings, in which:
As described hereinbefore, the method according to the present invention is applicable to any combination of the Allium plants. Examples of the Allium plants include onion (Allium cepa), Welsh onion, garlic (Allium sativum), scallion (Allium ascalonicum), and shallot.
The method of the present invention comprises four main steps. Two different protoplast donors are prepared from two different Allium plants in a first step which is followed by a second step wherein protoplasts are prepared from the protoplast donors. In a third step, the prepared protoplasts are subjected to cell fusion to provide hybrid cells. The hybrid cells are cultured to complete plant in a fourth step which may include incubation of the hybrid cells for callus formation prior to growth to complete plant.
Regarding the first step, each protoplast donor may be taken from various portions of starting Allium plants, grown or non-grown. Examples of the protoplast donor include a normal grown plant, a sterilized young plant obtained by incubating a leaf generating portion of a bulb, a plant derived from a growth point, a plant obtained by redifferentiation of callus, callus derived from a growth point, embryo-derived callus, and callus derived from other organs or tissues of a plant.
Particularly, when a growth-point-derived plant, growth-point-derived callus or embryo-derived callus is used as a protoplast donor, the hybrid cells obtained therefrom show a high potential of growth and/or differentiation. Further, when a growth-point-derived plant or growth-point-derived callus is used as a protoplast donor, the resulting hybrid plant can be made virus-free.
In the second step, both protoplast donors are treated by an enzyme solution to prepare respective protoplasts. The composition of the enzyme solution may be optionally determined depending on the kind of the protoplast donor or the starting plant.
In the third step, the respective protoplasts are subjected to cell fusion by using a known cell fusion technique. As a result, hybrid cells are formed in a background of non-fused cells and fused non-hybrid cells.
After the cell fusion, the hybrid cells may be sorted out and cultured separately from the other cells. Such cell sorting may be conducted visually in the visible region of light by the use of a microscope. The cell sorting may also be performed by the fluorescence microscopy wherein a fluorescence microscope enables distinction of the fused cells by coloring thereof under irradiation of blue excitation light.
The visible region cell sorting is described more in detail. It is now assumed that one of the protoplast donors is callus, whereas the other protoplast donor is a leaf blade of a plant. In such a combination, the protoplasts resulting from the callus are featured by being cytoplasm-rich (large cytoplasm with small vacuoles), while the protoplasts obtained from the leaf blade are characterized by the presence of chloroplasts which are green in the visible region of light. Thus, the wanted hybrid cells can be visually distinguished from the non-fused cells and the fused non-hybrid cells by the dual features of being rich in cytoplasm and having green chloroplasts.
However, it is possible that the resulting hybrid cells do not contain an enough number of chloroplasts, thereby failing to provide a distinct green color feature. In this case, the hybrid cells cannot be readily distinguished from the non-fused cytoplasm-rich cells or the fused non-hybrid cytoplasm-rich cells.
According to the fluorescence microscopy cell sorting method described above, the cell mixture is subjected to irradiation of blue excitation light to cause red coloring of the chloroplasts. Thus, under this condition, the hybrid cells can be readily distinguished from the other cytoplasm-rich cells by such coloring of the former.
It should be appreciated that the cytoplasm-rich hybrid cells can be readily distinguished from the non-fused leaf blade cells or fused non-hybrid lead blade cells which are not cytoplasm-rich. Alternatively, the hybrid cells may be later sorted from the non-hybrid leaf blade cells by selecting a suitable culture medium.
Preferably, prior to conducting the cell sorting, the hybrid protoplasts together with the non-fused protoplasts should be cultured to such an extent that cell membranes are regenerated. This is because the regenerated cell membranes protect against cell damaging upon picking up the subsequently sorted hybrid cells.
Further, after the cell sorting and picking up, the sorted hybrid cells may be preferably transferred into a nursing culture system which is used for incubating the hybrid cells prior to culturing thereof to complete plant. Specifically, the nursing culture system comprises a filter ring arranged within a Petri dish which contains, around the filter ring, protoplasts of an Allium plant having a high growing ability to serve as a nursing agent. The nursing protoplasts assist cell division of the hybrid cells.
In an alternative embodiment, the hybrid cells obtained as a result of the preceding cell fusion may be incubated for callus formation together with non-hybrid cells (non-fused cells and fused non-hybrid cells), and thereafter sorted out from the non-hybrid cells for growth to complete plant. In other words, the hybrid cells may be separated from the non-hybrid cells at the callus stage by utilizing different features of differently originated calluses. For example, the callus originated from garlic cells is known to be relatively compact (containing finer cells in a dense state) due to its high redifferentiation capability. The garlic callus is also featured by its yellow color. On the other hand, the onion callus tends to be friable (containing coarser cells) due to redifferentiation inability, and lacks a yellow color feature.
More specifically, it is now assumed that, in incubating onion-garlic hybrid cells together with onion cells (non-fused onion cells and fused non-hybrid onion cells) and garlic cells (non-fused garlic cells and fused non-hybrid garlic cells), a culture medium is selected which allows growth of the onion cells and the hybrid cells (because of the inherited onion features) while prohibiting growth of the garlic cells. In this case, only two kinds of calli (or calluses) are formed which include onion-cell-derived callus and hybrid-cell-derived callus. Of these, the hybrid-cell-derived callus is characterized in that it is compact and yellow because of the inherited garlic features. Thus, the hybrid callus can be easily sorted out from the onion callus before subsequent growth to complete plant.
The present invention will now be described further on the basis of more specific examples.
This example refers to a combination of onion and garlic. The process was conducted in the following order.
Protoplast donors were separately prepared with respect to onion and garlic.
First, an onion seed and a garlic bulb were sterilized by substantially the same method which includes the following sub-steps.
For preparing the onion protoplast donor, the sterilized onion seed was cultured in a modified BDS medium [1% agar medium containing 2,4-dichlorophenoxyacetic acid (hereafter abbreviated to 2,4-D) with molarity of 1.25x10⁻⁵ M] having the composition shown in the following Table 1 (see the next page). As a result, callus was derived from the growth point of a leaf generating portion of the seed. The thus derived callus was subcultured in a modified BDS medium (liquid medium containing 2.5x10⁻⁶ M 2,4-D). Two-day-old subcultured callus was used as the onion protoplast donor.
It should be understood that all the culture media used in the examples of the present invention were adjusted to pH5.6 with NaOH and subjected to filter sterilization.
For preparing the garlic protoplast donor, a leaf generating portion was excised with a scalpel from the sterilized garlic bulb, and thereafter cultured for about 1-2 weeks in a modified BDS medium [hormone-free 0.2% Gellan Gum medium (available from Kelco Division of Merck & Co., Inc., Japan)]. A sterile young plant resulted from such culturing. A leaf blade of the young plant was used as the garlic protoplast donor.
In the second process step, refined protoplasts were prepared respectively from the onion protoplast donor (cultured callus suspension) and the garlic protoplast donor (young plant leaf blade).
The onion protoplasts were prepared in the following way.
(I-2-A-a) The supernant of the onion culture suspension was removed, and about 0.5g of the onion callus (cell masses) was suspended in an enzyme solution (about 25ml) having the composition shown in the following Table 2. In Table 2, "MES" is an abbreviation of 2-(N-morpholino) ethane-sulfonic acid, whereas the term "MES Good's buffer" means a buffer solution obtained by dissolving 4.265g of 20mM MES.H₂O and 1.017g of 5mM MgCl₂.6H₂O in distilled water (total volume being 1 liter) and thereafter adjusting the solution to pH5.6 with NaOH.
(I-2-A-b) The cell liquid obtained above was shaked for about 5-6 hours by a gyrotory shaker (100rpm).
(I-2-A-c) The cell liquid was passed moderately through sieves of progressively decreasing mesh sizes (mesh sizes decreasing in the order of 150 µm, 90 µm, 60 µm, and 40 µm). As a result, coarser cells were removed, while wanted finer cells remained with the liquid.
(I-2-A-d) The filtered cell liquid was transferred into a precipitation tube after passing through another 40 µm sieve, and subjected to centrifugation for 3 minutes at 600rpm.
(I-2-A-e) The supernant of the centrifuged cell liquid was removed, and the sedimented cells were suspended in a washing liquid. This washing liquid was prepared by dissolving 22.77g of 0.5M mannitol and 0.09g of 2.5mM CaCl₂ in distilled water (total volume being 250ml) and thereafter adjusting the solution to pH5.6.
(I-2-A-f) The liquid obtained by the sub-step (I-2-A-e) was placed in a 10ml precipitation tube and subjected to centrifugal separation for 3 minutes at 600rpm, the centrifugal separation being conducted three times.
(I-2-A-g) Finally, the supernant of the centrifuged cell liquid was removed to provide refined onion protoplasts.
The garlic protoplasts were prepared, as follows.
(I-2-B-a) The leaf blade of the sterile garlic young plant was cut with a scalpel into square fragments (about 3mm in size).
(I-2-B-b) The obtained fragments were suspended in an enzyme solution (about 25ml) having the composition shown in the following Table 3.
(I-2-B-c) The suspension obtained above is shaked for about 5-6 hours by a gyrotory shaker (50rpm).
Subsequently, sub-steps similar to the sub-steps (I-2-A-c) to (I-2-A-g) for the onion protoplasts were performed to provide refined garlic protoplasts.
In the third step, the two kinds of protoplasts were subjected to cell fusion. For this purpose, two kinds of cell suspensions were prepared which respectively contained onion protoplasts and green garlic protoplasts at a concentration of 2x10⁵ cells/ml. The cell suspensions were then mixed together at a ratio of 1:1, and 0.8ml of the mixture was subjected to cell fusion by using Shimazu Cell Fusion Apparatus SSH-1 (Shimazu Corp., Japan). The cell fusion was conducted under the conditions shown in the following Table 4.
The protoplast suspension obtained by the preceding process step was subjected to centrifugal separation, and the supernant was removed. The resulting precipitate, which consisted of fused cells (hybrid cells and fused non-hybrid cells) and non-fused cells, was suspended in a modified 8p culture medium (containing 2.5x10⁻⁶ M 2,4-D) having the composition shown in the following Table 5 (see next page). 0.5ml of the thus obtained suspension was mixed with 0.5ml of another modified 8p culture medium [containing 2.5x10⁻⁶ M 2,4-D and 0.6% Sea Plaque agarose (FMC Corporation)] having been maintained at a temperature of 40°C. The mixture was then placed into a Petri dish of 35mm diameter and allowed to solidify, the mixture having a protoplast density of about 1x10⁵ cells/ml. Thereafter, the solidified mixture was incubated stationarily at 25°C in the dark for a period of about 10 days. During this stationary incubation, the modified 8p medium was supplemented every 4-5 days with about 0.05ml of a modified BDS medium having the composition already shown in Table 1.
It should be appreciated that the modified 8p medium was selected for the incubation because it prohibits colony formation with respect to the non-fused garlic protoplasts and the fused non-hybrid garlic protoplasts while allowing cell division of the onion protoplasts (the non-fused onion protoplasts and the fused non-hybrid onion protoplasts) and the hybrid protoplasts to enable colony formation.
After the stationary incubation, the agarose gel 1 was cut into pieces 2, as shown in Figure 1. Three of the cut pieces 2 were placed in a Petri dish (35mm diameter) containing 0.8ml of a modified BDS liquid medium (see Table 1). Thereafter, the culture system was subjected to shaking (50rpm) at 25°C in the dark for a period of about 30 days.
After colonial formation, the formed colonies were transferred into a modified BDS medium (containing 2.5x10⁻⁶ M 2,4-D and 0.2% Gellan Gum) for stationary culturing at 25°C, thereby forming calli. Of the calli thus formed, compact ones resulted from the hybrid cells, whereas friable ones originated from the onion cells.
One of the compact calli obtained in the foregoing step was placed in a 50ml Erlenmeyer flask which contained 5-10ml of a modified BDS liquid medium, and thereafter shaked at 50rpm. A similar operation was repeated until the callus was sufficiently multiplied.
The multiplied callus obtained in the preceding sub-step (I-5-a) was cultured at 25°C under 1,500-2,500 LUX light irradiation in a modified MS medium [containing 0.2% Gellan Gum, 5.4x10⁻⁶ M naphthalenacetic acid (NAA), and 8.9x10⁻⁶ M benzyladenine (BA)] having the composition shown in the following Table 6. As a result, an adventitous bud was formed upon lapse of about 4 months.
It should be appreciated that the modified MS medium does not allow the onion calli (the non-fused onion cells and the fused non-hybrid onion cells) to generate an adventive bud. Therefore, all of the calli (including the onion calli and the hybrid calli) may be cultured together in the modified MS medium wherein the onion calli drop out. For this reason, the prior sorting of the hybrid calli is not absolutely necessary.
In the final stage, the adventive bud obtained as a result of the redifferentiation was transferred into another modified 1/2 MS medium (modified MS medium diluted to a 1/2 concentration) containing 0.2% Gellan Gum for root initiation and generation of a young plant. The young plant thus obtained was then implanted on vermiculite for acclimation, and thereafter transferred to culture earth. As a result, a complete onion-garlic hybrid plant was produced.
This example differs from Example I only in the following respects.
In this example, the garlic protoplasts were prepared in the following way which is a substitute for the process step (I-2-B) of Example I.
Subsequently, the fragments were transferred into an enzyme solution (see Table 3) and processed in the same manner as in Example I, thereby providing refined garlic protoplasts.
The incubating step in this example was conducted in the following manner, as opposed to the process step (I-4) of Example I.
*Cytoplasm-rich and having chloroplasts which are green in the visible region of light.
*Cytoplasm-rich and having chloroplasts which are colored red under irradiation of blue excitation light.
Example II is otherwise the same as Example 1.
The present invention being thus described, it is obvious that the same may be varied in many ways. For instance, the invention is not limited to hybridization between onion and garlic, but equally applicable to any combination of the Allium plants. Further, the invention may be also applied to realize hybridization between different varieties of the same Allium species (e.g. garlic). Such variations are not to be regarded as a departure from the spirit and scope of the present invention, and all such modifications as would be obvious to those skilled in the art are intended to be included within the scope of the following claims.
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