IT202100021467A1 - MICROBIOLOGICAL PROCESS FOR OBTAINING HYBRID BAMBOO PLANTS - Google Patents

Description

MICROBIOLOGICAL PROCESS FOR OBTAINING

BAMBOO PLANTS HYBRID

The present invention relates to a microbiological process for the production of bamboo plants. hybrid that allows you to obtain bamboo plants in a simple, reliable, fast and economic way hybrid substantially free from disease and having large size, high speed? of growth and very high levels of mechanical resistance to compression and mechanical resistance to traction.

Among the bamboo plants giants, the Phyllostachys edulis, commonly called Moso, ? the most widespread throughout the world, extending over 7 million hectares in the People's Republic of China alone. Although in other countries its cultivation is more? recent and limited, in recent years yes ? significantly extended; for example, in Italy, that ? the European country with the most? large area planted with bamboo giant, in the last five years the extension of the cultivation of Phyllostachys edulis ? increased from a surface area of a few tens of hectares to over 2,000 hectares.

The reason for this sudden success of Phyllostachys edulis? that, in the face of reduced management costs, each of these plants guarantees income for almost a century and is? usable for over 1500 industrial applications in addition to food use, consequently arousing great interest.

Indeed, the Phyllostachys edulis ? kind of bamboo with the highest speed? of growth, given that the speed? of elongation of the culm (i.e. the barrel) ? even 1.00 meter per day.

However, Phyllostachys edulis does not have the greatest stem wall thickness and, consequently, does not have the greatest levels of compressive strength and tensile strength among bamboo species.

The object of the present invention is, therefore, to allow in a simple, reliable, fast and economic way to obtain bamboo plants. having large dimensions, high speed? of growth and very high levels of mechanical resistance to compression and mechanical resistance to traction.

Another purpose of the present invention ? to allow to obtain bamboo plants? substantially free from diseases pi? resistant to plant pathogens.

Is the specific object of the present invention a microbiological process for the production of bamboo plants? hybrid comprising the following stages:

A. performing a fusion of Phyllostachys edulis protoplasts and Phyllostachys Bambusoides protoplasts obtaining fusion products;

B. grow calluses in one or more? callus culture substrates starting from the fusion products obtained in step A;

C. generate bamboo plants? Hybrid Phyllostachys with meristematic technique starting from calluses grown in phase B.

According to another aspect of the invention, in phase A the fusion of protoplasts can take place chemically using polyethylene glycol (PEG) and/or sodium nitrate (NaNO3) and/or calcium ions acting as fuse.

According to a further aspect of the invention, the protoplasts of Phyllostachys edulis and the protoplasts of Phyllostachys Bambusoides of phase A can be obtained from the following preliminary phase:

D. isolating and growing in culture protoplasts from at least one Phyllostachys edulis plant and protoplasts from at least one Phyllostachys Bambusoides plant;

and after phase A and before phase B pu? be performed otherwise? the following step: E. regenerating cell walls of the fusion products obtained in step A obtaining fusion products having cell walls;

for which in phase B these corns have grown in one or more? callus culture substrates from the cell-walled fusion products obtained in step E.

According to an additional aspect of the invention, after phase A and before phase B it can be performed otherwise? the following stage:

F. selecting the fusion products obtained in step A;

for which in phase B these corns have grown in one or more? callus culture substrates from the selected fusion products obtained in step F.

According to another aspect of the invention, after phase E and before phase B it can be performed otherwise? the following stage:

F. selecting the cell-walled fusion products obtained in step E;

for which in phase B these corns have grown in one or more? callus culture substrates from selected cell-walled fusion products obtained in phase F.

According to a further aspect of the invention, after phase C it can be performed otherwise? the following stage:

G. providing at least one of the hybrid Phyllostachys plants generated in step C of a respective TAG based on RFID technology which stores information relating to said at least one plant that can be read by an app executed by a portable device.

According to an additional aspect of the invention, said information can comprise one or more? data selected from the group comprising data of a company and/or production laboratory of said at least one plant, a clone number of said at least one plant, geolocation data of said at least one plant of departure and of arrival of said at least one plant .

According to another aspect of the invention, said information can be encrypted.

According to a further aspect of the invention, said respective TAG can be an NFC TAG.

The advantages offered by the microbiological process of production of bamboo plants? hybrid according to the invention are numerous.

First, bamboo plants hybrid obtained by this microbiological process having large dimensions and high speed? of growth.

Furthermore, these bamboo plants hybrid have very high levels of mechanical resistance to compression and mechanical resistance to traction.

Furthermore, the bamboo plants hybrid obtained by the microbiological process according to the invention are substantially more? resistant to plant pathogens.

Furthermore, the microbiological process according to the invention allows a massive production of bamboo plants. hybrid all with the same characteristics.

Further, some embodiments of the invention allow the geographic location of bamboo plants to be remotely monitored. hybrid and/or their state of health.

This invention will come now described, for illustrative but not limiting purposes, according to preferred embodiments thereof.

The inventors have observed that the Phyllostachis Bambusoides, commonly called by the Japanese term Madake, ? some kind of bamboo having interesting mechanical characteristics which are better than those of Phyllostachys edulis. In fact, thanks to the significant thickness of the culm, which? greater than that of the Phyllostachys edulis, the Phyllostachis Bambusoides has absolutely the most? high in mechanical resistance to compression, equal to about 780 kg/cm2, and mechanical resistance to traction, equal to about 2480 kg/cm2, among all bamboo species. The culm of Phyllostachis Bambusoides ? therefore better than that of Phyllostachys edulis for use in construction, laminates and other industrial applications.

In light of this, the inventors have conducted research to develop hybrid Phyllostachys plants obtained from Phyllostachys edulis and Phyllostachis Bambusoides having the attractive characteristics of both, particularly including large size, high speed and of growth and very high levels of mechanical resistance to compression and mechanical resistance to traction.

because the Phyllostachys species flower every 80-100 years, the inventors have discarded the hybridization process of the pollen of the flowers of Phyllostachys edulis and/or Phyllostachis Bambusoides.

Otherwise, the inventors have developed a microbiological laboratory process for the production of hybrid Phyllostachys plants by crossing the species Phyllostachys edulis and Phyllostachis Bambusoides.

The preferred embodiment of the microbiological process according to the invention comprises a first step for isolating and culturing protoplasts from (at least) one Phyllostachys edulis plant and protoplasts from (at least) one Phyllostachys Bambusoides plant. As known, this phase includes the removal of the cell walls. The sources of protoplasts starting from (at least) one Phyllostachys edulis plant and from (at least) one Phyllostachys Bambusoides plant are advantageously preliminarily selected on the basis of the characteristics of the plants themselves, such as, for example, the speed? of growth, the diameter of the culm, the mechanical resistance and the development of the root system.

Subsequently, in a second phase, a fusion of protoplasts, also known as somatic hybridization, from Phyllostachys edulis and Phyllostachys Bambusoides is performed, in which all the nuclear and cytoplasmic chromosomal kit from Phyllostachys edulis and Phyllostachys Bambusoides is united without meiosis or gamete formation. Advantageously, the fusion of protoplasts takes place chemically by means of polyethylene glycol (PEG) and/or sodium nitrate (NaNO3) and/or calcium ions, acting as fusigens. It should be borne in mind that in other embodiments of the microbiological process according to the invention the fusion of protoplasts can take place also or alternatively electrically.

Then, a third step of cell wall regeneration of the fusion products, also known as induction of cell wall synthesis, is performed.

Subsequently, the fusion products provided with the cell wall regenerated in the third step are selected, in particular by selecting the fusion products on the basis of their characteristics, such as, for example, the quality? and the integrity? of the regenerated cell wall.

Then, in a fifth stage, calluses are grown by placing the selected fusion products in one or more? callus culture substrates.

Subsequently, in a sixth phase are the bamboo plants generated? Hybrid Phyllostachys with meristematic technique starting from calluses.

In this way, the microbiological process according to the invention is based on the in vitro cultivation of meristematic cells, also called plant stem cells, deriving from somatic hybridization, i.e. from the fusion of protoplasts, of Phyllostachys edulis and Phyllostachys Bambusoides, allowing to cross fabrics from Phyllostachys edulis plants and Phyllostachys Bambusoides plants, obtaining within a few weeks plants of hybrid Phyllostachys resulting from an intergeneric and interspecific hybridization and having crossed characteristics among the original donors, i.e. Phyllostachys edulis and Phyllostachys Bambusoides. In particular, the hybrid Phyllostachys plants obtained by means of the microbiological process according to the invention have excellent chemical, physical and physiological characteristics, and in particular they have large dimensions, high speed and of growth and very high levels of mechanical resistance to compression and mechanical resistance to traction.

In other words, the microbiological process according to the invention carries out a genomic transformation, i.e. a technique aimed at the union of somatic cells from the two species of bamboo? Phyllostachys edulis and Phyllostachys Bambusoides, in order to obtain a new genetic combination, i.e. a new germplasm.

In this regard, the microbiological process according to the invention overcomes the problems of incompatibility also present in the same species and the timing of 80-100 years to have the flowering of plants of Phyllostachys and therefore the timing of the normal hybridization from crossbreeding of pollens, all causes that prevent having a specific hybrid species of Phyllostachys through a procedure biological hybridization in a relatively short time. In fact, although for the bamboo species? several biological propagation techniques are known, such as the classic propagation from seed, rhizome division and culm cuttings, however these techniques suffer from serious drawbacks when it comes to large-scale or mass propagation. Most of the prior art biological propagation techniques are useful for small scale production and much depends on availability. of the mother plants. Large-scale propagation, with a production of between 10,000 and 500,000 plants per year, requires highly efficient techniques that many bamboo orchards lack. Therefore, for large-scale propagation, with a production greater than 500,000 plants per year, traditional nursery techniques, i.e. the biological techniques of the prior art are largely insufficient. Furthermore, the massive production of mother plants from seed, in the case of bamboo groves with potentially diseased seeds, brings with it the risk of virosis and mycoplasmosis.

Thus, the microbiological process according to the invention achieves better results in the large-scale production of hybrid Phyllostachys plants which are also disease-free, while also offering cost advantages.

The plants of hybrid Phyllostachys obtained by means of the microbiological process according to the invention allow the execution of remote monitoring methods of the plants themselves, to identify their geographical positioning and/or their state of health.

In particular, the hybrid Phyllostachys plants obtained by means of the microbiological process according to the invention can be marketed using a control system based on TAG NFC (Near Field Communication) technology. Through the Ethereum blockchain network, each plant is provided with a TAG, i.e. a passive transceiver electronic device, advantageously incorporated in a plate applied to the plant, which stores a unique identification code or a memorized certificate of the blockchain network.

The tag? readable through a specific application, or app, run by a smartphone, or by any other portable device such as a laptop or a tablet, equipped with an active NFC transceiver electronic device. The TAG of which ? provided the plant allows you to associate a series of encrypted information with the plant, for example the data of the company and/or production laboratory, the number of the clone, the geolocation of departure and arrival at the customer, most likely a farmer.

Given the high value of the commercialized plant material, the use of TAGs makes it possible to have a control panel at the company and/or the production laboratory, configured to display the geographical positioning of all the hybrid Phyllostachys plants obtained through the microbiological process according to the invention. The commercialized hybrid Phyllostachys plants are advantageously periodically detected, for example by means of the Sentinel-2 or Pleiades satellite system, currently having a spatial resolution of up to 0.5 metres. The satellite and multispectral images acquired and processed using specific algorithms also allow remote monitoring of the vigor index (NDVI), or the state of health, of the hybrid Phyllostachys plants obtained by the microbiological process according to the invention produced by the company and/or from the laboratory. Advantageously, on the basis of the information acquired and certified in blockchain with time stamp, ? possible to give personalized assistance to customers, e.g. farmers, provide them with information on how to optimize the crops and verify the agronomic actions they have implemented, as well as detect any unauthorized division or relocation operations of the commercialized plants. There? allows strict control of the plantations of hybrid Phyllostachys obtained by means of the microbiological process according to the invention, avoiding an uncontrolled development which in the past has sometimes led numerous bamboo groves to be abandoned due to neglect or poor management. Therefore, the preferred embodiment of the microbiological process according to the invention also allows a control and possible contrast of unauthorized multiplications of a high quality plant material such as hybrid Phyllostachys plants obtained by means of the microbiological process according to the invention.

It must be kept in mind that the TAG with which plants of hybrid Phyllostachys obtained by means of the microbiological process according to the invention are provided can be read using an RFID technology other than NFC technology.

In the foregoing the preferred embodiments have been described and variations of the present invention have been suggested, but ? to be understood that the experts of the branch will be able to make modifications and changes without with what? leave its scope of protection, as defined by the attached claims.

Claims (9)

1. Microbiological production process of bamboo plants? hybrid comprising the following stages: A. performing a fusion of Phyllostachys edulis protoplasts and Phyllostachys Bambusoides protoplasts obtaining fusion products; B. grow calluses in one or more? callus culture substrates starting from the fusion products obtained in step A; C. generate bamboo plants? Hybrid Phyllostachys with meristematic technique starting from calluses grown in phase B. 2. Microbiological process according to claim 1, wherein in phase A the fusion of protoplasts takes place chemically by means of polyethylene glycol (PEG) and/or sodium nitrate (NaNO3) and/or calcium ions acting as fusion generators. 3. Microbiological process according to claim 1 or 2, wherein the protoplasts of Phyllostachys edulis and the protoplasts of Phyllostachys Bambusoides of phase A are obtained from the following preliminary phase: D. isolating and growing in culture protoplasts from at least one Phyllostachys edulis plant and protoplasts from at least one Phyllostachys Bambusoides plant; and in which after phase A and before phase B is performed also? the following step: E. regenerating cell walls of the fusion products obtained in step A obtaining fusion products having cell walls; for which in phase B these corns have grown in one or more? callus culture substrates from the cell-walled fusion products obtained in step E. 4. Microbiological process according to claim 3, wherein after phase A and before phase B another the following stage: F. selecting the fusion products obtained in step A; for which in phase B these corns have grown in one or more? callus culture substrates from the selected fusion products obtained in step F. 5. Microbiological process according to claim 3, wherein after phase E and before phase B another the following stage: F. selecting the cell-walled fusion products obtained in step E; for which in phase B these corns have grown in one or more? callus culture substrates from selected cell-walled fusion products obtained in phase F. 6. Microbiological process according to any one of the preceding claims, wherein after step C is also carried out the following stage: G. providing at least one of the hybrid Phyllostachys plants generated in step C of a respective TAG based on RFID technology which stores information relating to said at least one plant that can be read by an app executed by a portable device. 7. A microbiological process according to claim 6, wherein said information comprises one or more data selected from the group comprising data of a company and/or production laboratory of said at least one plant, a clone number of said at least one plant, geolocation data of said at least one plant of departure and of arrival of said at least one plant . 8. Microbiological process according to claim 6 or 7, wherein said information is encrypted. 9. Microbiological process according to any one of claims from 6 to 7, wherein said respective TAG ? an NFC tag.