Microsoft Word - 48dallavecchia.docx CHEMICAL ENGINEERINGTRANSACTIONS VOL. 49, 2016 A publication of The Italian Association of Chemical Engineering Online at www.aidic.it/cet Guest Editors:Enrico Bardone, Marco Bravi, Tajalli Keshavarz Copyright © 2016, AIDIC Servizi S.r.l., ISBN978-88-95608-40-2; ISSN 2283-9216 Abscisic Acid Production: Biotechnology Process Development and Scale-up Loretta Aloisio, Ilaria Lebano , Emanuela Servo, Daniela M. Spera* Consortium of Research Applied to Biotechnology – CRAB Via S. Pertini 106, 67051 Avezzano (AQ) Italy spera@crabavezzano.it In the last years it’s noted a growing interest in the use of microorganisms, and their metabolites, in agriculture. Microorganisms studied are those naturally present in the soils. Attention was focused on microorganisms producing abscissic acid (ABA). Their possible uses are in pre- and in post- harvest practices. ABA production was studied on laboratory scale, then costs were estimated for ABA industrial production that were compared with those of the products, containing ABA, on the market. The maximum ABA production rate (calculated by Monod model) is the one corresponding to B. cinerea in YD, at 298K, no stirring and sunlight, equal to 1.08E-8 kg m-3 s-1. In order to produce ABA with a cost lower than 20,000 €, it’s estimated that is necessary to have a bioreactor size between 15 - 20 m3. Relative investments costs estimates are about 1,400,000 €. To maintain supernatant, stream ABA rich, production cost below 1 €/kg, size bioreactor must be about 10 m3, its relative investment costs are estimated about 1,300,000 €. 1. Introduction Traditional agricultural practices have the disadvantage of not being able to provide inexpensive products in large quantities. A part of this traditional farming now takes the name of organic farming (BIO), which represents a sizeably niche market with medium-high prices; anyway this practice cannot avoid the use of chemical additives for fertilization, for the control of pathogens, for the maintenance of the sensory characteristics of the products and to ensure quality standards comparable to non-BIO products. Today these productions are very popular. This scenario is compatible with an increase in the use of additives with biological criteria. In this context, biotechnology can offer alternative solutions based on products of natural origin. ABA was identified and characterized in 1963 by Frederick Addicott and his staff during a study of the substances responsible for abscission of the fruits of the cotton plant. Two substances were isolated, abscissina I and II, now called ABA, ubiquitous substance in the vascular plants. The first real demonstration of the production of ABA by a fungus was reported by Assante et al. (1977) who discovered a fungus, Cercospora rosicola, causing the appearance of brown spots on the leaves of rose, able to produce in liquid culture ABA (0,06 kg m -3). Since then, it has been found that other species were able to produce ABA in vitro: most are plant pathogenic fungi. This suggests that ABA production by fungi may have a possible role in phyto-pathogenesis. There are no data regarding ABA production in plants during the process of fungal infection. ABA is responsible for multiple effects and currently the commercial formulations containing this hormone are used in agriculture for different applications, in particular to: - improve plant tolerance to various types of environmental stress (especially to water stress); - delay the rate of growth of plants; - treat the fruit in pre-harvest. ABA has also insecticidal capacity. Microorganisms used in this work for ABA production were Botrytis cinerea and Cercospora rosicola. Data obtained in the laboratory scale tests were used to estimates industrial production costs of ABA. DOI: 10.3303/CET1649023 Please cite this article as: Aloisio L. , Lebano I., Servo E., Spera D., 2016, Abscisic acid production: biotechnology process development and scale-up, Chemical Engineering Transactions, 49, 133-138 DOI: 10.3303/CET1649023 133 2. Methods Cercospora rosicola (CBS n° 138.35) was purchased from CBS and Botrytis cinerea (ATCC n° 90870) was purchased from ATCC. The two strains, delivered in frozen form in vials coated by dry ice, were revitalized: the vials were placed in a water bath at a temperature of 25 to 30 ± 0.1 ° C until completely thawed (about 5 minutes). Following thawing, vials were cleaned with 70% ethanol. 50 µl of material were aseptically transferred in the reference medium: on plate and in broth. The mediums were used, respectively, PDA and PD; the plates and the flasks were incubated in a thermostat at 24 ± 0.1 ° C; the growth of the strains was checked regularly during incubation and after 7-10 days was observed the presence of viable colonies both on the plate and in broth. For the maintenance of these strains we were performed every two weeks on the ground skim PDA and the plates were incubated in a thermostat at 25 ± 0.1 ° C for 4-5 days. To estimates industrial production costs SuperPro Designer ® Software was used. 2.1 Medium Composition Medium composition for strains growth were: YPD (Yeast extract 50 kg/m3, Y, peptone 50 kg/m3, P, Dextrose 200 kg/m3, D) with addition of starch; YD (yeast extract 50 kg/m3, Y, Dextrose 200 kg/m3, D) with calcium carbonate (CaCO3 100 kg/m 3YDC) or without; PDA (infused potatoes 4kg/m3, P, Dextrose 20 kg/m3, D, Agar 15 kg/m3, A); PD (infused potatoes 4 kg/m3, P, Dextrose 20 kg/m3, D). 2.2 Analytical methods ABA determination was performed using the "Phytodetek® ABA Test Kit" (Agdia) as reported in Annex procedure. Method Enzyme-Linked Immunosorbent Assay (ELISA) of competitive type for ABA determination was used. The concentration of ABA in the unknown samples was obtained using a straight line of from 0 to 6E-5 kg/kg calibration. 3. Experimental plan Table 4 shows the experimental plan carried out. Types of medium, temperature, different exposure to sunlight and agitation speed were varied. In each test as inoculum (0.05 m3 m-3) a microorganism culture in exponential phase (spores 51 days aged) was used. Each of the test was carried out in three replicates. Botrytis cinerea was used in the tests from 1 to 10; Cercospora rosicola in the tests from 11 to 20 (Table 1). Table 1: Operating conditions of tests carried out. Tests from 1 to 10 refer to B. cinerea, those from 11 to 20 C. Rosicola. * Exposure at natural sun light Test 1-11 2-12 3-13 4-14 5-15 6-16 7-17 8-18 9-19 10-20 Medium YPD+starch YPD+starchYPD+starchYPD+starchYD YDC YD YDC YD YDC Length (h) 480 480 480 480 528 528 1,008 1,008 1,872 1,872 Temperature (K) 298±0.1 298±0.1 298±0.1 301±0.1 298±0.1298±0.1298±0.1 298±0.1 298±0.1298±0.1 Llight exposure* No Yes No NO Yes Yes Yes Yes Yes Yes Stirring (rad s-1) 0 0 10.47 0 0 0 0 0 0 0 In each flask sterile gauze pads were introduced that act as inert material and allow fungus to adhere and produce spores to improve fungal growth, morphology, and production of secondary metabolites bioactive as described by (Bigelis et al., 2006). More particularly, the immobilization on an inert support is able to protect the biomass, support the growth of the mycelium and improve the fungal activity (Rodriguez-Couto et al., 2009). It was observed that in some cases the biomass immobilized on a support shows a higher enzyme production, approximately 2÷25 times, compared to the one observed when the cells are free to move (Gao et al., 2010). On this basis we hypothesized that supporting Cercospora rosicola, and Botrytis cinerea on solid material it’s possible to obtain a large quantitative of hormone such as ABA. To confirm this, tests were planned with only sterile gauze pads as inert material. In addition, the calcium carbonate (CaCO3) was added to the minimal medium YD (YDC), to have a more tenacious adhesion of the biomass to the inert matrix (gauze). Samples were taken for any test, at regular time intervals, to determine ABA production. The mycelium was recovered at the end of the test and was rinsed with distilled water 3-4 times to remove traces of medium. Then it was dried in a vacuum oven at 353K for 4h to obtain also dried weight. The differences in production of ABA and biomass between the two fungal strains at different times and at different conditions were evaluated using ANOVA (Systat 13). 134 4. Results and discussion 4.1 Experimental data In Figure 1 ABA production data obtained in the better tests (Test 9, Test 10, Test 19 and Test 20 as described in Table 1) are reported. Figure 1: ABA production in better tests (T9, T10, T19, T20) The maximum ABA production rate (calculated by Monod model Eq(1) and Eq(2)) is the one corresponding to B. cinerea in Test 9 – YD, 298K, no stirring, sunlight – equal to 1.08E-8 kg m-3 s-1. μ = μmax ⋅ S k+S (1) where: S: initial concentration of reference substrate (kg m-3) μmax: maximum production or growth rate (kg m -3 s-1); calculated as reported in Eq(2) in exponential phase K: Monod constant dX dt = μ ⋅ X (2) where: X: ABA or cells concentration (kg m-3) μ: maximum production or growth rate (kg m-3 s-1). For Test9 the biomass production rate was equal to 4.4E-7 kg m-3s-1. This data were used in the estimation of ABA industrial production costs. 4.2 Estimation of ABA industrial production costs To estimate ABA industrial production costs the SuperPro Designer® software was used. SuperPro Designer is a valuable tool in process development, process engineering, and manufacturing. SuperPro provides under a single umbrella modeling of manufacturing and end-of-pipe treatment processes, project economic evaluation, and environmental impact assessment. The results obtained showed that the different sets of physical conditions (light, temperature and stirring) did not affect the production of ABA. Due to this result, estimation were done in the most economical conditions to reduce the energetic cost of the process. In particular it was hypothesized that the strains growth is done at natural light, at room temperature (25±0,1 °C), without stirring. Block diagram of process simulated for industrial ABA production is reported in Figure 2. Medium component are mixed (3/MX-101) than stored (2/V-101). Medium is feed at bioreactor (1/F-101). To simulate bioreaction hypotheses were: continuous process, temperature 298K, residence time to simulated exponential production, and growth, rate, air flow 2.5E-4 m 3 m-3 s-1, reaction stoichiometry as reported in Eq. (1) 0 10 20 30 40 50 60 70 0 500 1000 1500 2000 A B A (1 E 6 kg /k g) Time (h) Test9 Test10 Test19 Test20 135 150 Glucose + 5 Air + 25 Yeast Extract→ 160 Biomass + 0.1 Debris + 10 ABA + 9.9 H2O (1) Broth is stored (4/V-102) before centrifugation (5/BC-101). Centrifuge performance are those reported in Table 2. Sediment is stream rich in biomass instead supernatant is ABA rich. Table 2: Operating conditions of industrial centrifuge simulated Component Biomass Debris Glucose ABA Protein Water Recovery in sediment (kg/kg) 0.98 0.6413 0 0 1 0 2 / V-101 Media prep 3 / MX-101 Mixing Acqua YE Glucosio Ter 1 / F-101 Cont Frmn Terreno Aria IN Aria OUT 4 / V-102 Accumulo brodo Brodo 5 / BC-101 Centrifuga Brodo1 Sedimento Supernatante Figure 2: Block diagram of simulated process for industrial ABA production Supernatant is the stream of interest (ABA rich). Yields, investment costs, operative costs and ABA production costs were calculated as below described. In Table 3 industrial process yields for 3 m3 bioreactor are reported; in Table 4 characteristics and costs of major equipment are described. Table 3: Estimated process yields. 3 m3 bioreactor Sediment Supernatant t/y 623.6 1.9 Table 4: Characteristics and costs of major equipment 3 m3 bioreactor (Figure 2) Equipment V-101 (0.11m3) F-101 (1.4m3) V-102 (0.165m3) BC-101 Auxiliary equipment TOTAL Cost (€) 15,000 250,000 20,000 120,000 101,250 506,250 Other hypotheses are: 250 operating day for year; 3 consecutive eight-hour shifts for 2 people per shift. Purchase cost for industrial plant was estimated equal to 506,250 €. In Table 5 investment costs for industrial plant are reported. Table 5: Investment costs for industrial plant 3 m3 bioreactor (Figure 2) Equipment (€) Design, construction management, authorizations (€) Civil works, structures (€) Engineering, contingenties (€) TOTAL 506,250 24,300 74,925 32,400 637,875 In Table 6 costs items for industrial plant are reported. It was hypothesized to sell sediment at 1.50 €/kg in order to have other revenue (935,000 € for industrial plant with 3 m3 bioreactor). ABA production cost was estimated equal to 27,750 €/kg for 3 m3 bioreactor; this cost is compatible with ABA commercial price. 136 Table 6: Production costs of ABA for industrial plant 3 m3 bioreactor (Figure 2) Depreciation (€/y) Medium (€/y) Staff salaries (€/y) Utilities (€/y) Maintenance (€/y) Operating costs (€/y) Revenue sediment (€/y) Supernatant production costs (€/kg) ABA production costs (€/kg) 63,787.50 100,000 180,000 565,840 31,893.75 941,521.25 935,000 3.44 27,750 It’s possible to estimate supernatant (stream ABA rich) production cost equal to 3.44 €/kg. Supernatant production cost was estimated because some results, not reported, demonstrated that supernatant is useful in pre-harvest to speed up the ripening process of some fruits and its cost it’s very competitive. Same iter was used to estimate ABA production costs vs. different bioreactor size (Figure 4); this is useful to define plant size in order to have profit. In Figure 3 supernatant production costs v. bioreactor size are reported. In order to produce ABA with a cost lower than 20,000 €, it’s possible to estimate that is necessary to have a bioreactor size between 15 - 20 m3. Relative investments costs estimates are about 1,400,000 €. To maintain supernatant production cost below 1 €/kg, size bioreactor must be about 10 m3, its relative investment costs are estimated about 1,300,000 €. Figure 3: Surnatant production cost vs Bioreactor size Figure 4: ABA production cost vs Bioreactor size - 1,00 2,00 3,00 4,00 5,00 6,00 7,00 8,00 - 10,00 20,00 30,00 40,00 S u rn a ta n t p ro d u ct io n c o st (€ ) Bioreactor size (m 3) - 50.000,00 100.000,00 150.000,00 200.000,00 250.000,00 - 10,00 20,00 30,00 40,00 A B A p ro d u ct io n c o st ( € ) Bioreactor size (m 3) 137 5. Conclusion The results obtained showed that both the selected microbial strains are able to produce ABA. Some of the different sets of physical choices conditions tested (light, temperature) did not affect the ABA production. It is instead necessary to use gauze to promote adhesion and, consequently, the growth of the mycelium and production of ABA. The maximum ABA production rate (calculated by Monod model) is the one corresponding to B. cinerea in YD, at 298K, no stirring and sunlight, equal to 1.08E-8 kg m-3 s-1. Using the SuperPro Designer® software it was possible to simulate, with data obtained in laboratory scale, an industrial process (Figure 2) for ABA production. This software was useful to estimate investment cost, operative costs and ABA production cost. Acknowledgments This work is dedicated to Stefano Bianchini, died prematurely, who started the experiments on abscisic acid production in CRAB Laboratories. References Assante W.B., Merlini L., Nahimi G., 1977, Abscissic acid, a metabolite of the fungus Cercospora rosicola, Experientia. 33, 1556-1557. 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