Attitude of Evros’ s Farmers for the Genetically Modified Trees Stavros Valsamidis1, Ioannis Petasakis2, Elpida Tenidou3, Lambros Tsourgiannis4 1 Department of Accounting and Finance, EMaTTech Institute of Technology, Kavala, Agios Loukas, 65 404, Kavala, Greece, e-mail: svalsam@teikav.edu.gr 2 Department of Accounting and Finance, EMaTTech Institute of Technology, Kavala, Agios Loukas, 65 404, Kavala, Greece, e-mail: jpetasakis@hotmail.com 3 Department of Accounting and Finance, EMaTTech Institute of Technology, Kavala, Agios Loukas, 65 404, Kavala, Greece, e-mail: elpida.tenidou@gmail.com 4 Department of Accounting and Finance, EMaTTech Institute of Technology, Kavala, Agios Loukas, 65 404, Kavala, Greece, e-mail: ltsourgiannis@gmail.com Abstract. Genetically modified trees are now one more expression of human intervention in nature. As for other people is a suicidal mood at the cost of profit maximization, for others is an inevitable trend for the survival of continuing growing world population that gathers several advantages, a survey of those directly involved in the primary sector, farmers, and deemed necessary. The implementation of this research includes the completion of 100 questionnaires from farmers in the region of Evros. Then, using the widely used Excel and SPSS software packages are processed research results with the discovery of useful correlations. The results show that in the region of Evros opinions of farmers who have negative attitude to the cultivation of genetically modified forest trees is much more (70) versus those with positive (30). Both trends express their concern on different characteristics, the systematic mapping of which is attempted in this work. The intension to cultivate genetically modified trees in relation to the demographic characteristics of the farmers, the farm size, the farm size and the type of cultivation are also investigated. Keywords: Genetically Modified Forest Trees, Evros, Farmers, Analysis of attitudes. 1 Introduction Biotechnology is characterized as the technology of biological processes using organisms, or parts of their processes for the manufacture or production of useful or commercially exploitable substances and to provide services for the benefit of man (Thieman and Palladino, 2008). According to the Convention on Biological Diversity, biotechnology is defined as any technological application uses biological systems, living organisms or 401 their derivatives to create or modify products for specific use (Convention on Biological Diversity, 1992). This definition includes medical and industrial applications as well as the tools and techniques used in agriculture and food production (FAO, 2004). The term denotes a wide range of processes, from the use of earthworms for protein production by the production of human genes, such as growth hormone. In biotech products include pharmaceutical proteins, foods, detergents, etc., while a variety of applications including the services of waste water and waste as a medical diagnosis, or achievements of gene therapy (EuropaBio, 2012). Biotechnology today, builds on the achievements of modern molecular biology and uses a number of techniques, including genetic engineering (recombinant DNA), Methods and tissue engineered cell cultures on a large scale, the polymerase chain reaction, etc. It has numerous applications in health sciences, environmental protection (eg use in waste management), agriculture, livestock and industry. Together with biomedical technology, which the development of technologies with applications in medicine, biotechnology sometimes called biological engineering (Walter and Menzies, 2010). In fact the term biotechnology includes a broad set of tools and application of these tools. Genetic engineering only started in 1982 when (Palmiter et al., 1982) created the first genetically modified or otherwise transgenic mice. Genetic engineering may be new but the creation of new agencies with modified genetic material, can be done relatively quickly. Agricultural biotechnology concerns mainly Genetically Modified Trees (GMT) and is particularly interesting since the first seeds of GM in America planted. The commercial sale of genetically modified food began in 1994, when Calgene brought first marketed the slow ripening tomato (Clive, 1996). According to the World Health Organization (WHO), Genetically Modified Trees are trees whose genetic material (DNA) has been altered in a way not found in nature. This technology is often called modern biotechnology or gene technology and sometimes recombinant DNA technology or genetic engineering (WHO, 2002). According to Sedjo (2004) a plant comprising introducing a gene using an approach beyond sex (nonsexual) considered bioengineered plant and designated as a transgenic. Among the various techniques used to generate transgenic plants, Agrobacterium transformation is the most widely used tool, representing 80% of the transgenic plants produced (Broothaerts et al., 2005). The term GM crops refer to crop plants created with the latest technologies used molecular biology and which plants intended for consumption by humans or animals. The modification is done in laboratory conditions and its goal usually is to support them in a desirable feature, for example resistance to herbicides or improved nutritional content (Varzakas et al., 2007a). Over the last two decades there have been significant developments in biotechnological applications. The overall coverage in a survey (Sedjo, 2004) and the working paper (Preliminary review of biotechnology in forestry, 2004) present that the cultivation of GM foods and crops include dynamic technology, potential risks to public health and safety of ecosystems, powerful economic lobbies, impact on small surface areas and small farmers, nutritional promises and scandals, political strategies, European 402 directives and easy identification of citizens with actual or potential problems and injustices arising from their use. Furthermore, the use of GM forest trees in commercial plantations would contribute to increased forest productivity, improved pulp for paper, biofuel production, climate change mitigation, preservation of biodiversity and reduction of energy, pesticides and fertilizers utilization (Sedjo 2006, Chapotin and Wolt 2007, FAO 2008, 2010, Hinchee et al. 2009, Flachowsky et al. 2009, Harfouche et al. 2011). While these practices may perhaps increase profits for wood and paper products firms, the high economic, ecological and social costs associated with industrial tree plantations are paid by those living in and around large scale plantations and by society at large (Carman et al 2006). The working group led by Professor Athanasios Tsaftaris (2004), the former Minister for Rural Development and Food, among other findings, discovers a reluctance of Central Macedonia farmers in dealing with the agro-biotechnologies. The Greeks generally have negative attitudes towards the cultivation and consumption of GM trees and products, and there seems to be consensus among politicians and citizens in their opposition to genetically modified (Kousis, 2009). Greece has, so far, chosen the cultivation of GM trees mainly because of the small agricultural clergy, the geomorphological features, different microclimates and soil conditions favor the biological and integrated crop (Varzakas et al., 2007b). Furthermore, the application of GM technologies to trees has raised a number of potential public concerns. Many of these concerns, although not all, are the same raised for GM annual crop plants, including the potential for spread of antibiotic or herbicide resistance genes to other non-target species from GM trees; the potential for long – distance pollen spread over many years from long – lived trees, the potential for adverse effects on biodiversity from forests of GM trees; and any unexpected effects (Gartland et al 2003).e Public acceptance in particular is influenced by environmental, public health and socio-cultural concerns, which have been raised mainly by opinion influencing groups. Concerns often focus on potential genetic flow between GM and wild trees and consequent implications for the natural environment, increased use of broad spectrum herbicides, more pesticide resistant forest trees, negative effects on forest tree fitness, potential higher vulnerability of forest trees to viral and other diseases, increased soil decomposition, adverse effects on biotrophic processes in host ecosystems, flowering suppression and cultural adaptation to altered biodiversity conditions due to transgene escape (El- Lakany 2004,Van Frankenhuyzen and Beardmore 2004, Williams 2006, Sedjo 2006, Farnum et al. 2007, FAO 2008, 2010). In the Eurobarometer survey, (European Community, 2010) becomes apparent the opposition of the Greeks towards GM crops. While a small, relatively, a majority of Europeans (54%) believes that genetically modified foods are not good for them and their families, in Greece the percentage of those who oppose reaches 78%. The Greeks, in 89%, believe that it is fundamentally unnatural. Furthermore, 85% expressed huge concerns on security issues. As the former Minister of Rural Development and Food as Professor of Genetics and 403 Biotechnology at AUTH, expressed concern for possible adoption of personal views in formulating national agricultural policy (Journal Ling, 2012). On the other hand, according to Tsourgiannis et. al. (2013), (2014), (2015a), (2015b) it appears that there might be potential buyers of products derived from GM trees and more particular for wood products, woody biomass energy products and paper products originating from transgenic plantations in Greece. Indeed, most of these potential consumers willing to purchase transgenic wood products base their buying decisions on economic issues (Tsourgiannis et. al. 2013, 2014, 2015a, 2015b). Taking into consideration that most of these products are not directly linked with human health impacts, there is a potential for development of a market for such products, particularly in current times of economic depression. The Peter Coventry (2001) argued that the Forest Council in the US should allow the certification of GM tree plantations as "well managed" by the effects of GM trees with reduced lignin in soils in relation to the physical produced. The Zolotov (2003) mentions the success of GM maize crops in the United States and expresses concern about the low rates of crops in Europe. Despite initial skepticism about whether biotechnology in forestry can also be related to environmental issues, including the effects on organisms associated with tree living and ecosystems, are presented and benefits from genetic modification of lignin (Axelsson et al., 2010). The reasons for not widespread commercial use of biotechnology research presented in 90 specific US (Strauss et al., 2009). The transgenic biotechnology can help the forest improvement programs, but can also simultaneously be of concern for the safety of the environment. Today there is an urgent need to establish a European platform to build on this knowledge of GMT (Gallardo et al., 2011). Due to the negative public opinion about the GMT, the Strif and Broshe (2001) proposed to focus the efforts of the whole enterprise in producing trees which are not intended for consumption by humans or animals. For example, crops for the manufacture of fibers such as cotton or flax. Developments in the field of GMT in plant industry have led to increased crop production and yield in turn have increased the use of genetically modified (GM) foods in the human food chain. The use of genetically modified foods for human consumption has raised a number of fundamental issues such as the ability of genetically modified foods cause potentially harmful immunological side effects like allergic hypersensitivity (Prescott and Hogan, 2006). Kuiper and Kleter (2003) do compare the safety of conventional food with respect to genetically modified food. Interesting aspects about genetically modified trees in forests, are the ethical considerations (Gamborg and Sandoe, 2010), the relevant environmental concerns in forests (Fladung et al., 2010), social, legal and regulatory issues related to genetically modified plants (Sedjo, 2010). The paper is organized as follows. Section 2 describes the approach. Section 3 describes the results for both descriptive statistics and advanced analysis. Section 4 presents discussion about the results together with directions in the future. 404 2 Approach This study proposes an approach for analyzing the attitudes of farmers in the region of Evros regarding the Genetically Modified Trees. The research method used was simple random sampling. Information was recorded following an interview with each farmer individually. The questionnaire consists of three parts. The first part comprises three farmers' attitude questions regarding Genetically Modified Forest Trees with analytical control of many individual factors. The second part includes the recording demographics of farmers. Finally the third part includes the recording of operating data for each of 100 farmers. The questionnaire includes mainly qualitative data that is data stored in non-numeric form in contrast to quantitative data that are in numerical form. The quality is the data that describe the characteristics or properties held by an object (Strauss and Corbin, 1998). The properties are categorized into classes that can then be assigned a numerical value. There is no significance to these data values, simply object characteristics. In some areas of social research, the distinction between qualitative-quantitative data has led to prolonged disputes where each group supports the superiority of its own data type (Trochim and Donnelly, 2006). The 'quantitative' claim that their data is strictly reliable and scientifically while 'quality' that their are respectively sensitive, detailed and contextual. Therefore, we suggest the following assumptions: H1: The cultivation intention is related to the gender of the farmer. H2: The cultivation intention is related to the age of the farmer. H3: The cultivation intention is related to the level of education. H4: The cultivation intention is related to the farm size. H5: The cultivation intention is related to the type of cultivation. The analysis performed includes both descriptive statistics and advanced analysis using X2 test. 3 Results Here are the results after data processing in Excel software packages 2007 and SPSS 18.0. 405 3.1 Descriptive Analysis The sample is 100 farmers in the region of Evros, in the North East Greece. 55 of them are male and 45 are women. 65 are married and for 65 of them farming is their main occupation. Table 1. Distribution of the sample based on the knowledge of the term GMT. Knowledge of the term Number Percentage Know 100 100,0 Table 2. Distribution of the sample by the intention of cultivation. Cultivation intention Number Percentage No 70 70,0 Yes 30 30,0 Total 100 100,0 Table 3. Distribution of the sample by age. Age Number Percentage 20-29 35 35,0 30-44 25 25,0 45-64 35 35,0 65+ 5 5,0 Total 100 100,0 60% of the farmers in the sample are younger than 44 years old. Table 4. Distribution of the sample based on educational level Education Number Percentage Primary school 25 25,0 Secondary school 15 15,0 High School 40 40,0 University 20 20,0 Master / Doctorate 0 0,0 Total 100 100,0 The distribution of the sample based on educational level is presented at table 4. 80% has graduated in High school or lower and only 20% are graduates of university. 406 Table 5. Distribution of the sample based on the number of children Number of children Number Percentage None 30 30,0 1-2 kids 60 60,0 3+ Children 10 10,0 Total 100 100,0 Table 6. Distribution of the sample by age of child Age of children Number Percentage No children 35 35,0 Small children (0-12 years) 15 15,0 In adolescents (13-18 years) 15 15,0 Large (18+ years) 35 35,0 Total 100 100,0 Table 7. Distribution of the sample by farm size Farm size Number Percentage <10 acres 25 25,0 11-50 acres 15 15,0 51-100 acres 10 10,0 101-200 acres 50 50,0 Total 100 100,0 Table 8. Distribution of sample by type of cultivation Type of crop Number Percentage Arable 15 15,0 Vegetables 35 35,0 Orchards 10 10,0 Groves 10 10,0 Forest plantations 30 30,0 Other 0 0,0 Total 100 100,0 3.2 Advanced Analysis The results of the Chi-Square test regarding the hypotheses of section 2, are presented in this subsection. 407 Table 9. Cultivation intention in relation to gender Cultivation of GMT Female Male Total No 30 40 70 Yes 15 15 30 Total 45 55 100 There is no dependence to gender (value of Pearson Chi-Square= is 0.433, df=1, p- value=0.511). Table 10. Cultivation intention in relation to age Age Cultivation of GMT Total 20-29 30-44 45-64 65+ No 20 10 35 5 70 Yes 15 15 0 0 30 Total 35 25 35 5 100 There is dependence to age (value of Pearson Chi-Square= is 30.612, df=3, p- value<0.001). Younger farmers are less negative to the cultivation of GM forest trees. Table 11. Cultivation of GMTs in relation to level of education Level of education Total Would you cultivate GMTs? Primary Secondary High University school school School No 25 10 20 15 70 Yes 0 5 20 5 30 Total 25 15 40 20 100 There is dependence to level of education (value of Pearson Chi-Square= is 18.651, df=3, p-value<0.001). It is worth to notice that farmers with basic education and university graduates are the most negative to the cultivation of GMT. 408 Table 12. Cultivation of GMTs in relation to farm size Farm size Would you cultivate GMTs? Total <=10 acres 11-50 acres 51-100 acres 101-200 acres No 5 10 10 45 70 Yes 20 5 0 5 30 Total 25 15 10 50 100 There is dependence to the farm size (value of Pearson Chi-Square= is 43.651, df=3, p-value<0.001). Farmers who own less or equal to 10 acres, responded that would cultivate GMT in 80%. Table 13. Cultivation of GMTs in relation to the type of cultivation Type of cultivation (crop) Total Would you cultivate GMTs? Forest Arable Vegetables Orchards Groves plantations No 5 20 10 5 30 70 Yes 10 15 0 5 0 30 Total 15 35 10 10 30 100 There is dependence to the type of cultivation (value of Pearson Chi-Square= is 31.406, df=4, p-value<0.001). Farmers. Farmers who cultivate arable and vegetables are these who mostly would accept the cultivation of GMTs. Table 14. Distribution of cultivation factors in median and percentile points (quartiles) Cronbach’s Factor 25% Median 75% Alpha Q2a 2,50 3,50 4,00 Q2b 1,00 3,50 4,00 Q2c 1,00 3,50 5,00 Q2d 1,75 3,00 3,00 Q2e 1,00 2,50 3,00 0.854 Q2f 1,00 2,00 3,25 Q2g 1,00 1,00 2,00 Q2h 1,00 1,00 1,25 Q2i 1,00 1,00 1,00 The Cronbach’s Alpha value is 0.854. 409 We create a new variable which is the average value of all factors of table 15. Its mean value is 2.17 (standard deviation 0.69). Table 15. Relation of cultivation with gender gender N Mean Female 15 2,5926 cultivation Male 15 1,7407 Males seem to be more positive about cultivation compared to Females (t=4.271, df=14, p-value=0.001). Table 16. Relation of cultivation with type of cultivation 95% Confidence Interval for Mean N Mean Lower Upper Std. Deviation Bound Bound Arable 5 1,8889 ,00000 1,8889 1,8889 Vegetables 20 2,3056 ,25964 2,1840 2,4271 Orchards 10 3,1667 ,99553 2,4545 3,8788 Forest plantations 30 2,6667 ,00000 2,6667 2,6667 Other 70 2,4444 ,89224 2,1113 2,7776 Total 70 2,4841 ,76678 2,3013 2,6670 The willingness of farmers not to cultivate genetically modified products depends on the type of crop (F4,65 = 3.555, p = 0.011). Those with orchards are on average from 0.13 to 2.4 higher willingness not to cultivate genetically modified compared with those with arable (p-value = 0.018). Similarly those who have Orchards have, on average, from 0.1 to 1.7 higher willingness to cultivate non-GM compared to those with Vegetables (p-value = 0.0028). Table 17. Relation of cultivation with farm size 95% Confidence Interval for Mean N Mean Lower Upper Std. Deviation Bound Bound <10 acres 5 2,5556 ,00000 2,5556 2,5556 11-50 acres 10 3,3333 ,81985 2,7468 3,9198 51-100 acres 10 2,4444 ,35136 2,1931 2,6958 101-200 acres 45 2,2963 ,74724 2,0718 2,5208 Total 70 2,4841 ,76678 2,3013 2,6670 410 The willingness of farmers not to cultivate genetically modified products depends on the farm size (F3,66 = 6.130, p = 0.001). Those who have croplands from 11 to 50 acres have, on average from 0.04 to 1.7 units, higher willingness not to cultivate genetically modified comparatively with those who have from 51 to 100 acres (p-value = 0.033). Similarly those who have croplands from 11 to 50 acres have, on average from 0.4 to 1.7, higher willingness not to cultivate genetically modified comparatively with those who have from 101 to 200 acres (p-value = 0.001). Table 18. Distribution of non cultivation factors in median and percentile points (quartiles) Factor 25% Median 75% Cronbach’s Alpha Q2p 2,50 4,00 5,00 Q2q 1,00 1,00 2,00 Q2r 1,75 2,50 3,25 Q2s 1,00 2,00 3,25 Q2t 2,00 3,00 4,00 0.820 Q2u 1,00 3,00 3,25 Q2v 1,75 3,00 4,00 Q2w 1,00 3,00 3,25 Q2x 1,00 1,00 1,00 The Cronbach’s Alpha value is 0.820. We create a new variable which is the average value of all factors of table 18. Its mean value is 2.48 (standard deviation 0.77). Table 19. Relation of type gender with the possitiveness about non cultivation q4a N Mean Std. Deviation Female 30 2,6852 ,70399 q2second Male 40 2,3333 ,78567 Males and females does not differ according to possitiveness about non cultivation compared to Females. (t=1.937, df=68, p-value=0.057) Table 20. Relation of type of cultivation with the willingness of farmers to cultivate GMT 95% Confidence Interval for Mean N Mean Lower Bound Upper Bound Arable 10 2,6667 2,5829 2,7505 Vegetables 15 2,1481 1,7648 2,5315 Forest Plantations 5 1,2222 1,2222 1,2222 Total 30 2,1667 1,9091 2,4242 411 The willingness of farmers to cultivate genetically modified products depends on the type of crop (F2.27 = 13.764, p = 0.001). Those who cultivate arable are on average from 0.7 to 2.1 higher willingness to cultivate genetically modified compared with those who cultivate forest plantations (p-value = 0.001). Similarly those who cultivate vegetables are on average from 0.3 to 1.5 higher willingness to cultivate genetically modified compared with those who have forest plantations (p-value = 0.001). Table 21. Distribution of attitude factors vs the use of biotechnology (quartiles) Factor 25% Median 75% Cronbach’s Alpha Q3a 2,00 2,50 4,00 Q3b 1,00 3,00 4,00 Q3c 2,00 3,00 3,75 Q3d 1,00 3,00 3,00 Q3e 2,25 3,50 4,00 Q3f 3,25 4,00 5,00 0.915 Q3g 1,00 5,00 5,00 Q3h 4,00 5,00 5,00 Q3i 3,25 5,00 5,00 Q3j 1,00 3,00 3,00 Q3k 1,00 3,00 3,75 4 Discussion and Conclusions The aim of this study was to investigate the attitudes of farmers regarding the GMT. From the beginning there was the limitation of the number of responses. All the responders come from the same area (Evros). So possible generalized conclusions would be unreliable. Nevertheless the value of the study in precious as it is the first study in Greece which examines the farmers attitudes towards the use of biotechnology in forest tree sector. In this research confirmed the continued negative attitude of the majority of farmers in relation to the cultivation of GMT, which has been recorded by the relevant survey reports Eurobarometer (European Commission - EC, 2010). In general, elder people with low education, mainly female, with large scale farms seems not to be in favour of cultivating transgenic trees whilst most of the younger, high educated, mainly male, small scale farmers are more positive towards the cultivation of GM trees. In a constantly changing world, the persistence of the established notions of the past creates rigidities and barriers to future challenges. On the other hand the respect of values and tradition is essential for any organization. Somewhere there must be "balance" one for cultivation or not GMT. 412 According to Mc Donell et al (2010), the current decade will be important for researchers of trees. 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