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Transgenic Rice Plants Essay Research Paper The

Transgenic Rice Plants Essay, Research Paper


The following form contents were entered on 15th Apr 97


Date = 15 Apr 97 23:58:50


subject


= School Sucks


resulturl = http://www.schoolsucks.com/thanks/


name = Sarah


Lenhardt


email = sxl63@po.cwru.edu


publish = yes


subject = Biology


title


= Transgenic Rice Plants


papers = Please put your paper here.


Transgenic


Rice Plants that Express


Insect Resistance


For centuries, rice has been


one of the most important staple crops for the world and it now currently feeds


more than two billion people, mostly living in developing countries. Rice


is the major food source of Japan and China and it enjoys a long history of


use in both cultures. In 1994, worldwide rice production peaked at 530 million


metric tons. Yet, more than 200 million tons of rice are lost each year to


biotic stresses such as disease and insect infestation. This extreme loss


of crop is estimated to cost at least several billion dollars per year and


heavy losses often leave third world countries desperate for their staple food.


Therefore, measures must be taken to decrease the amount of crop loss and


increase yields that could be used to feed the populations of the world. One


method to increase rice crop yields is the institution of transgenic rice plants


that express insect resistance genes. The two major ways to accomplish insect


resistance in rice are the introduction of the potato proteinas


e inhibitor


II gene or the introduction of the Bacillus thuringiensis toxin gene into the


plant’s genome. Other experimental methods of instituting insect resistance


include the use of the arcelin gene, the snowdrop


lectin/GNA (galanthus nivallis


agglutinin) protein, and phloem specific promoters and finally the SBTI gene.


The introduction of the potato proteinase inhibitor II gene, or PINII,


marks the first time that useful genes were successfully transferred from a


dicotyledonus plant to a monocotyledonous plant. Whenever the plant is wounded


by insects, the PINII gene produces a protein that interferes with the insect’s


digestive processes. These protein inhibitors can be detrimental to the growth


and development of a wide range of insects that attack rice plants and result


in insects eating less of the plant material. Proteinase inhibitors are of


particular interest because they are part of the rice plant’s natural defense


system against insects. They are also beneficial because they are inactivated


by cooking and therefore pose no environmental or health hazards to the human


consumption of PINII treated rice.


In order to produce fertile transgenic


rice plants, plasmid pTW was used, coupled with the pin 2 promoter and the


inserted rice actin intron, act 1. The combination of the pin 2 promoter and


act 1 intron has been shown to produce a high level, wound inducible expression


of foreign genes in transgenic plants. This was useful for delivering the


protein inhibitor to insects which eat plant material. The selectable marker


in this trial was the bacterial phosphinothricin acetyl transferase gene (bar)


which was linked to the cauliflower mosaic virus (CaMV) 35S promoter. Next


the plasmid pTW was injected into cell cultures of Japonica rice using the


BiolisticTM particle delivery system. The BiolisticTM


system proceeds as


follows:


Immature embryos and embryonic calli of six rice materials were


bombarded with


tungsten particles coated with DNA of two plasmids containing


the appropriate


genes.


The plant materials showed high frequency


of expression of genes when stained


with X-Gluc. The number of blue


or transgenic units was approximately 1,000.


After one week, the transgenic


cells were transferred onto selection medium


containing hygromycin


B. After two weeks, fresh cell cultures could be


seen on bombarded


tissue. Some cultures were white and some cultures were blue.


Isolated cell


cultures were further selected on hygromycin resistance. However,


no


control plant survived.


Then twenty plates of cells were bombarded with


the PINII gene, from which over two hundred plants were regenerated and grown


in a greenhouse. After their growth, they were tested for PINII gene using


DNA blot hybridization and 73% of the plants were found to be transgenic.


DNA blot hybridization is the process by which DNA from each sample was digested


by a suitable restriction endonuclease, separated on an aragose gel, transferred


to a nylon membrane, and then finally hybridized with the 1.5 kb DNA fragment


with pin 2 coding and 3′ regions as the probe. The results also indicate that


the PINII gene was inherited by offspring of the original transgenic line,


that the PINII levels were higher among many of the offspring and that when


PINII levels rose in wounded leaves, the PINII levels in unwounded leaves also


rose. However, the PINII gene is not 100% effective in eliminating insects


because it does not produce an insect toxin, just a proteinase inhibitor.


Yet, greater insect resistance can be achiev


ed by adding genes to produce


the Bacillus thuringiensis or BT toxin.


Bacillus thuringiensis is an entomocidal


spore-forming soil bacterium that offers a way of controlling stem boring insects.


Stem borers such as the pink and striped varieties are difficult to control


because the larvae enter the stem of the plant shortly after hatching and continue


to develop inside the plant, away from the toxins of sprayed insecticides.


Therefore, the stable institution of the BT gene into the rice plant’s genome


would provide a method of reaching stem borers with toxins that are expressed


in the plant tissues themselves.


Bacillus thuringiensis is comprised of


so-called cry genes that encode insect specific endotoxins. Recently some


lower varieties of rice, such as Japonica, have been successfully transformed


with cry genes, but the real challenge lies in transforming Indica rice, an


elite breeding rice that composes almost 80% of the world’s rice production.


In order to transform Indica rice, the synthetic cry IA gene must be used


because it is the only cry gene to produce enough of the BT protein. Next,


the synthetic cry IA gene under the control of the CaMV 35S promoter is attached


to a CaMV cassette for hygromycin selection of transformed tissues. Following


the linkage of the cry IA and the CaMV 35S cassette, the DNA is delivered to


the embryonic cells by particle bombardment with a particle inflow gun. More


specific transformation includes the following:


Immature Indica rice embryos


were isolated for ten to sixteen days after pollination from other greenhouse


plants and were plated on a solid MS medium containing sucrose (3%) and


cefotaxime.


After twenty four hours, embryos were transferred to a thin layer of highly


osmotic medium containing a higher percentage of sucrose (10%), were incubated,


and then were bombarded with plasmid pSBHI and gold particles by the particle


inflow gun. After bombardment, the thin layer of 10% sucrose was placed on


the layer of 3% sucrose. This sandwich technique allowed continuous adaptation


of the target tissue to the osmotic conditions, which was shown to be optimal


for callus induction. After twenty four hours, the 10% sucrose layer was removed


and the embryos were cultured on the 3% sucrose layer. After one week, they


were transferred to a 3% sucrose medium that was selected for hygromycin B


resistance. After a further three to four weeks, regenerated plants were transferred


to soil and placed in the greenhouse under


appropriate conditions. The results


of this process were eleven transgenic plants out of a total of thirty six.


Transgeneicy of the rice plants was confirmed by similar banding patterns


in Southern blotting. The presence of the BT protein was also demonstrated


in Western blot analysis, where a protein with the expected size of sixty-five


kilobases was found in all plants tested. Interestingly enough, the BT protein


levels were higher in older plants than in younger plants, possibly questioning


the role of inheritance of BT gene. Yet,

inheritance was determined by using


DNA blot hybridization, which revealed a segregation ratio of 3:1. This indicates


the integration of all copies of transgene at a single locus.


To assess


the mortality rate among different insects, both petri dish assays and whole


plant assays were performed. In petri dish assays, mortality rates were as


follows:


European corn borer = 85-95%


Yellow stem borer = 100%


Striped stem


borer = 100%


Cnaphalocrocis medinalis (leaffolder) = 67%


Marasmia patnalis


(leaffolder) = 55%


In whole plant assays, no surviving insects were found


on any BT expressing plants, although insects still survived on the control


plants or non expressing BT plants.


In addition to this recent insertion


of the BT gene into Indica rice, a similar procedure was conducted on Shuahggei


36, a variety of Indica rice. Transgeneicy of Shuahggei 36 was achieved by


taking plasmid P41ORH, which contained the coding region of the BT gene with


the marker CaMV 35S-HPI-NOS plus 1.0 kb of DNA fragment, and inserting it into


the pollen tube pathway. More specifically, the plasmid DNA was applied at


the cut ends of rice florets from one to four hours after pollination. Next


the seeds that were harvested were germinated under hygromycin B resistance.


However only 3% of the plants survived hygromycin resistance. After this,


the seedlings from the second generation were again segregated for hygromycin


resistance. From these seeds, seventy plant lines were screened for transgeneicy


and fifteen displayed the BT protein. These results and the inheritance of


the BT gene into offspring were confirmed by Southern blotting. Nevertheless,


the question remains whether the BT gene was really


integrated into the genome


or whether it was expressed only as a plasmid.


The use of the arcelin gene


is another experimental method of creating transgenic rice plants. The arcelin


gene is a translationally enhanced Bacillus thuringiensis toxin construct that


is effective on the rice water weevil. The rice water weevil or RWW is the


major pest of the Texan rice crop. Previously, the RWW was combated by granular


carbofuran, an insecticide that kills the RWW but has deleterious effects on


water fowl that live in the crop area. So environmentalists have forced the


cessation of the use of granular carbofuran and therefore, new methods have


to be developed. One of the major genes that confer resistance to the RWW


is the arcelin gene. Arcelin is a lectin that was originally discovered in


the seeds of bean cultivators that showed resistance to the Mexican bean weevil.


Next, researchers isolated a genomic clone encoding arcelin from the bean


seed and then placed it under regulation of a rice actin promoter. Then the


clone with the rice promoter was introduced into rice protoplast


s. Transgeneicy


and inheritance was then confirmed by genomic DNA blots and immunochemical


blots. In two separate experiments, six transgenic rice plants were subjected


to RWW infestation under controlled conditions. The results of the first experiment


are that similar numbers of RWW larvae were recovered from each set of six


plants, but the size of those from arcelin expressing plants were significantly


smaller. In the second experiment, although many normal larvae were recovered


from control plants, only three small larvae came from arcelin expressing plants.


This would indicate the benefits of inserting the arcelin gene into rice plants


for RWW resistance.


Another experimental method of creating transgenic rice


plants that are insect resistant includes the use of snowdrop lectin or galanthus


nivallis agglutinin (GNA). Snowdrop lectin helps to control the sporadically


serious pest the brown planthopper (BPH), which has developed a resistance


to many pesticides. Luckily for the environment, snowdrop lectin provides


high levels of toxicity to BPH but not to other animals. BPH is a member of


the order Homoptera and feeds by sucking the phloem sap from the stems of rice


plants. The major problem with combating BPH is that rice plants can not be


engineered for BT toxin resistance against this pest because BT toxins that


effect Homopterans have not yet been discovered or reported. Therefore, other


types of genes had to be manipulated in order to produce insect resistance


against BPH. The best plant protein that provides resistance to BPHs turns


out to be snowdrop lectin, and this was first confirmed by artificial diet


bioassays. To create the transgenic rice


plants, embryonic cell suspension


cultures were initiated from mature embryos from two Japonica rice varieties,


Taipei 309 and Zhonghua 8. Next, the protoplasts isolated from these cell


suspension cultures were transformed by using the plasmid pSCGUSR, containing


the nos-npt II gene as a selectable marker. Plasmid uptake was then induced


by the PEG process and geneticin was used as a selection agent. Geneticin


was added to the protoplast-derived colonies during the four and eight cell


stages. From this, more than fifty putative transgenic plants have been regenerated


from one thousand resistant colonies.


Another way of combating the brown


planthopper is by producing phloem-specific promoters. These promoters are


necessary because phloem is the exact site of feeding for the BPH. Although


the CaMV promoter is active in phloem tissue, the possibility exists to institute


a promoter from a gene that is specifically expressed only in phloem. This


would be advantageous if there are other parts of the plant that may be negatively


affected by the promoter and in this scenario, they would be unaffected. Recently,


a phloem specific promoter has been obtained from the rice sucrose synthase


gene RSs 1. RSs 1 promoter was used to drive the snowdrop lectin or GNA protein.


The results were confirmed by the use of immunological assays and they indicated


that not only is the gene being expressed in the phloem tissues, but that the


protein product has been successfully transported to phloem sap.


Unfortunately,


RSs 1 is heavily expressed in the seeds of rice plants, so an alternative promoter


called PP2 is currently under study. So far, PP2 has been purified and partially


sequenced. Also, a full cDNA library has been created for the gene and it


has been used to probe a genomic library to obtain the corresponding gene.


The promoter region form the PP2 gene is now being assayed.


One final


method of creating insect resistance in rice plants is the use of the SBTI


gene. SBTI gene is a trypsin inhibitor that acts against pests such as the


yellow stem borer and the gall midge. Greater insect resistance can be created


by introducing the Kunitz soybean trypsin inhibitor (SBTI) gene into varieties


of Indica rice plants. First, a PCP product corresponding to the protein was


isolated by oligonucleotide primers. Then, the resulting fragment was cloned,


sequenced and expressed in E. coli cell cultures. The results were a recombinant


SBTI gene that effectively fought off gall midges and yellow stem borers.


Presently, the SBTI gene is being cloned into vectors and is being used to


transform other types of embryos using the particle gun technique.


In


conclusion, through the use of new technologies such as the introduction of


potato proteinase inhibitor II gene, the establishment of the Bacillus thuringiensis


toxin gene and the experimental methods of using the arcelin gene, the snowdrop


lectin/GNA (galanthus nivallis agglutinin) protein, and phloem specific promoters


and finally the SBTI gene, rice plants have become almost completely resistant


to insects that used to destroy much of the crop. This has been an important


step in biotechnology because the improvement of rice plants is a major concern


that could potentially effect almost all of the populations of the world.


Biotechnology has become an increasingly accepted method of solving some of


the major problems in agriculture, medicine, and industry. Potentially, with


the advancements of many techniques, almost whenever people eat, drink, take


medicine, or go to work, they will be touched in some way by the many complicated


processes of biotechnology, that are striving to make our world a bette


r


place to exist in.

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