Free amino nitrogen improvement in sorghum malt brewing By Luke Mugode Submitted in partial fulfillment of the requirements for the degree MSc (Agric) Food Science and Technology in the Department of Food Science Faculty of Natural and Agricultural Sciences University of Pretoria PRETORIA June 2009 ©© UUnniivveerrssiittyy ooff PPrreettoorriiaa DECLARATION I declare that the dissertation herewith submitted for the degree MSc (Agric) Food Science and Technology at the University of Pretoria, has not previously been submitted by me for a degree at any other University or Institution of higher education. ii ABSTRACT Free amino nitrogen improvement in sorghum malt brewing By L. Mugode Supervisors: Prof. J.R.N. Taylor Prof: L.W. Rooney Although sorghum malt is relatively rich in free amino nitrogen (FAN), the 150 mg FAN/L threshold recommended for brewing is difficult to obtain. The vitreous nature of the sorghum endosperm hinders proteolysis during brewing. Hence, exogenous proteolytic enzymes are often required to increase hydrolysis of sorghum malt protein to produce sufficient FAN in order to support rapid yeast growth during fermentation. Ten exogenous proteases were examined for their production of FAN in sorghum malt mashing. Mashing was done at 550C for 45 minutes. Levels of FAN, as determined by the ninhydrin method, showed great variation among the proteolytic enzymes, ranging from 96 in control to 182 mg/100 g malt with possibly of most effective proteolytic enzyme. The variation in FAN level was possibly due to different optimal mashing conditions of exogenous proteases used and perhaps due to low ratios of exopeptidase/endopeptidase in the enzyme preparations. Low temperature (400C) and long duration mashing for (7 hours) gave good FAN production during mashing to a total of 113 and 138 mg/100 g malt in control and the treatment with exogenous proteolytic enzyme Flavourzyme plus malt, respectively. The exogenous enzyme (Flavourzyme) plus potassium metabisulphite (PMB) increased FAN production during mashing in the ratio of 2 to 1 in a treatment where PMB was added compared to one without. Similarly, hot wort extract (HWE) increased by 8% during mashing with exogenous enzyme plus PMB compared to one without PMB, respectively. PMB was involved in destabilizing the disulphide bonds in the sorghum protein iii polypeptide chains allowing proteolytic enzymes better accessibility to proteins. The increase in HWE was possibly due to the starch being freed from the sorghum protein matrix. Sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE) showed some oligomeric and polymeric kafirins after mashing. With transmission electron microcopy (TEM), protein bodies of varying sizes with partially degraded peripheral edges and some holes were seen after mashing. SDS-PAGE and TEM results suggest insufficient proteolysis. High protein digestibility sorghum’s potential for brewing was examined with reference to FAN production. Although during mashing FAN increased by approx. 82 and 115% for unmalted normal and high digestibility sorghums, respectively, the 150 mg FAN/L threshold, recommended for brewing was not achieved. FAN production to levels above 150 mg/L may only be realized if normal sorghum malt or high protein digestibility sorghum malt is mashed with exogenous enzymes containing sufficient exopeptidases coupled with appropriate mashing conditions. iv ACKNOWLEDGEMENTS I would like to express my gratitude to Profs: J. R. N. Taylor, and L. W. Rooney. Studying under supervision of these noble and experienced scientists is an experience I will live to treasure for the rest of my professional life I am also indebted to the International Sorghum and Millet Collaborative Research Support Program, (INTSORMIL) for the financial support to enable me undertake this MSc, under the leadership of the two named dignified scientists, the Zambian National Institute for Scientific Research (NISIR) for granting me a study leave and other assistance. I am also grateful to Novozymes SA (Pty) Ltd; in particular Mr J. van Aswegen, Mr I. Kennedy and Mr B. Higgins for their technical and material contribution to this study. Incomparable gratefulness go to Bradly Lawrence Cotterell for his enormous input particularly in research chapter 4.2, Mr. Chisala C. Ng’andwe with whom I shared pleasure and anguish, particularly in various research protocol standardization. Mr. Allan Hall from the Microscopy and Microanalysis Laboratory of the University of Pretoria is thanked for his priceless contribution to this work. Dr Janet Taylor is appreciated greatly for rendering enormous technical support in laboratory work and her critical care in times when hope was almost lost, particularly when I tragically lost my mother in-law. The one time “Easter Treat” away from home is a moment I will also live to cherish. To members of staff of the Department of Food Science of the University of Pretoria for their support and valuable input is highly appreciated. To my wife, and children, and my surviving Mom Irene, for their continuous moral support, I am deeply thankful. v TABLE OF CONTENTS DECLARATION ii ABSTRACT iii ACKNOWLEDGEMENTS v TABLE OF CONTENTS vi LIST OF TABLES viii LIST OF FIGURES ix 1. INTRODUCTION 1 2. LITERATURE REVIEW 3 2.1 Sorghum grain structure and chemical composition with particular reference 3 to proteins 2.2 Principles and practice of malting and brewing 7 2.3 The science of sorghum malting with particular reference to proteolysis 16 2.4 Mashing science with particular reference to proteolysis 16 2.5 Review of improving FAN when mashing with sorghum malt 17 2.6 Use of exogenous proteases with particular reference to sorghum lager beer 17 brewing 2.7 Conclusions 19 3. HYPOTHESES AND OBJECTIVES 20 3.1 Hypotheses 20 3.2 Objectives 21 4. RESEARCH 22 4.1 Effects of different commercial proteases on free amino nitrogen (FAN) 25 production and their impact on hot water extract when mashing with malted sorghum 4.1.1 Introduction 26 4.1.2 Materials and methods 26 4.1.3 Results and discussion 33 4.1.4 Conclusions 46 vi 4.1.5 References 47 4.2 Effect of high protein digestibility sorghum cultivars on free amino 54 nitrogen (FAN) production during mashing 4.2.1 Introduction 55 4.2.2 Materials and methods 56 4.2.3 Results and discussion 59 4.2.4 Conclusions 72 4.2.5 References 73 5. GENERAL DISCUSSIONS 76 5.1 Methodological considerations 76 5.2 Effectiveness of proteolytic enzymes in sorghum endosperm protein matrix 81 degradation 5.3 Practicality of employing a long protein rest at low temperature for production 82 of free amino nitrogen 5.4 Prospects of using high protein digestibility sorghums in lager beer brewing 83 6. CONCLUSIONS AND RECOMMENDATIONS 84 7. REFERENCES 85 vii LIST OF TABLES Page Table: 2.1 Amino acid compositions of protein fractions from the 6 endosperm,germ and pericap of Barnard Red sorghum Table:4.1.1 Effect of various exogenous proteases supplied by Novozymes on 33 FAN production when mashing with sorghum malt for 45 minutes at 550 Table:4.1.2 Effect of various exogenous proteases supplied by Kerry-Biosciences 34 on FAN production when mashing with sorghum malt for 45 minutes at 550C Table:4.1.3 Effects of exogenous protease (Flavourzyme), with (PMB) on 37 mashing with malted sorghum at low temperature for 7 hours on FAN and HWE Table:4.1.4 Effects of Flavourzyme and potassium metabisulphite (PMB) on the 40 wort amino acid profile of sorghum malt protein after mashing at 40oC for 7 hours Table:4.2.1 Germinative energy (GE) (%) for normal and high protein digestibility 59 sorghum cultivars Table 4.2.2 Effects of malting on protein digestibilities of normal and high protein 62 digestibility sorghum cultivars Table:4.2.3 Effects of mashing with unmalted grains of normal and high protein 64 digestibility sorghum cultivars for 45 minutes at 55°C on FAN production Table:4.2.4 Effects of mashing with malted normal and high protein digestibility 65 sorghum cultivars for 45 minutes at 55oC on FAN production Table:4.2.5 Effect of exogenous protease (Flavourzyme) on FAN production when 67 mashing with unmalted normal and high protein digestibility sorghum cultivars for 45 minutes at 55oC Table:4.2.6 Effects of exogenous protease (Bioprotease P. Conc.) on FAN 68 production when mashing with unmalted normal and high protein digestibility sorghum cultivars for 45 minutes at 55oC Table:4.2.7 Effect of exogenous protease (Flavourzymes) on FAN production 70 when mashing with malted normal and high protein digestibility sorghum cultivars for 45 minutes at 55oC Table:4.2.8 Effect of exogenous protease (Bioprotease P.conc) on FAN 71 production when mashing with malted normal and high protein digestibility sorghum cultivars for 45 minutes at 55oC viii LIST OF FIGURES Figure:2.1 A section of sorghum kernel 4 Figure:2.2 Simplified flow diagram of the malting process 7 Figure:2.3 Self-emptying conical steep tank with a mixing “geyser” with rotating 10 hollow arms and aeration rings Figure:2.4 Flat-bed (Nordon type) steeping tank 11 Figure:2.5 Outdoor floor malting of sorghum 12 Figure:2.6 Saladin box compartment type (a general view of germination vessel, 13 fan and conditioning chamber) Figure:2.7 Simplified diagram of the lager beer brewing process 14 Figure:2.8 A shortened double decoction process lasting for 2 ½ hours 17 Figure:4.1.1 Flow chart of experimental design for research chapter 4.1 23 Figure:4.1.2 Flow chart of experimental design for research chapter 4.2 24 Figure 4.1.3 Mashing profile for sorghum malt 29 Figure:4.1.4 Effects of Flavourzyme and potassium metabisulphite (PMB) on FAN 39 production during mashing at low temperature Figure:4.1.5 SDS-PAGE of malted sorghum malt proteins after mashing at low 43 temperature (40°C) for 7 hours Figure:4.1.6 Effects of Flavourzyme and potassium metabisulphite (PMB) on malt 45 protein after low temperature mashing for 7 hours at 40oC (TEM) Figure:4.2.1 Effect of malting normal and high protein digestibility sorghums on malt 60 fresh weight basis ix 1. INTRODUCTION Sorghum (Sorghum bicolor (L.) Moench) is a cereal that has significant genetic variability with more than 30,000 selections present in the world collections in India and elsewhere (Serna-Saldivar and Rooney, 1995). It is believed that sorghum plant is native to equatorial Africa (Serna-Saldivar and Rooney, 1995). It is now distributed throughout the semi-arid equatorial regions and other semi tropics of the world. The sorghum plant is uniquely well adapted to these conditions in that it is drought-resistant and will withstand periods of flooding. In fact, sorghum can produce a crop in these regions, where other cereals such as barley and maize cannot be economically cultivated (Doggett, 1988). Sorghum is the fifth most important crop in the world after wheat, maize, rice and barley International Crops Research Institute for the Semi-Arid Tropics/ Food and Agriculture Organization (ICRISAT/FAO, 1996). The leading producers during 1999-2003 periods include the USA 10.4 million metric tons (MT), India 8.5 million MT, Nigeria 8.1 million MT, Mexico 6.5 million MT and Sudan 4.4 million MT (ICRISAT/FAO, 1996). In Africa, the major sorghum growing areas run across West Africa south of the Sahara to the coast and eastward into Sudan, Ethiopia, and Somalia (House, 1995). Sorghum is a staple food crop of millions of poor people in semi-arid tropics of Africa and Asia. Moreover, it has gained increasing importance as a fodder (green/dry) and feed crop in the last decade (ICRISAT, 1996). In some countries, the trend of per capita agricultural production index for cereals has progressively been increasing during the past 25 years (1980-2005) (FAO, 1996). Although both area and production of sorghum in Eastern and Southern Africa has increased from the early 1970's to 2005, there has not been an increase in yield (ICRISAT, 1996). However, the use of sorghum in commercial production of lager and stout beers (Taylor et al., 2006), may motivate producers of sorghum and boost production and income to smallholder farmers as the case is in Uganda and elsewhere where sorghum is being utilized for lager beer (Mackintosh and Higgins, 2004). The potential of sorghum as an alternative substrate for lager beer brewing was recognized over five decades ago (Owuama, 1997). Success in replacing barley malt using sorghum malt in lager beer brewing has been cited in several parts of Africa, particularly in Nigeria and elsewhere (Agu and Palmer 1998; Owuama, 1997). In sub-Saharan African countries, Nigeria has been the leading country in using sorghum for lager beer production. This development came about due to government ban on importation 1