Methanogenesis

Methanogenesis

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  SUBMITTED BY-SURENDER RAWAT
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  • Methanogenesis isthe biological production of CH4 from either CO2 plus H2 or from methylated organic compounds. • Process of methanogensis was first demonstrated over 200 years ago by Alessandro Volta. • The process is strictly anaerobic. • All known methanogenic bacteria belong to Archaebacteria. • They are also called methanogens. • A variety of unique coenzymes are involved in methanogenesis.
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  Methanogens belong tothe Archaea group of Prokaryotes. They can be classified as Chemolithotrophic methanogens and Methylotrophic methanogens. Methanogenic bacteria are extremely oxygen sensitive. Methanogens require anaerobic conditions . They are found in the digestive systems of herbivores, marshes or lake bottoms, all sorts of mud sediments and in man made anaerobic digestors in sewage treatment plants.
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  Complex organic compoundscannot be utilised by methanogens. They use only C1 compounds and the only C2 compound: Acetate. There are two nutritional groups of methanogens. • Obligate chemolithotrophic methanogens that grow with CO2 plus H2 according to the equation:- CO2 + 4H2 CH4 + 2H2O • Some of these organisms live with the Quasi-chemolithotrophic substrates HCOOH and CO 4HCOOH 4CO2 + 4H2 CO2 + 4H2 CH4 + 2H2O
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   Methylotrophic methanogensthat grow with methyl group containing substrates for eg. Methanol, methylamines, acetate  The reaction for acetate is: CH3COOH CH4 + CH2  Organisms such as Methanosarcina barkeri grow on methanol or methylamines. Here, one fourth of the substrate has to be oxidised to CO2 for reducing power generation. CH3OH + H2O CO2 + 6H 3CH3OH + 6H 3CH4 + 3 H2O 4CH3OH 3CH4 + CO2 + 2 H2O  Group 2 organisms produce methane directly from methyl groups and not via CO2.  Obligate chemolithotrophic methanogens do not contain cytochromes which are present in methylotrophic methanogens
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  • The firsttwo novel coenzymes discovered in methanogens are coenzyme M and coenzyme F420 • Coenzyme M is a simple chemical compound . Its reactive group is the mercepto group which can be methylated and methyl coenzyme M is the ultimate precursor of mehane. • Coenzyme F420 is a deazaflavin, it is a redox carrier and its role is analogous to that of ferrodoxin in other anaerobes. • It functions as electron acceptor of hydrogenase and as electron donor in several reduction reactions. • Tetrahydromethanopterin and Methanofuran are involved in CO2 reduction. Methanofuran is the primary CO2 aceeptor.
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  Methane formation fromCO2 and H2 by Barker’s scheme. • The first carrier molecule is Methanofuran. • In a reaction that requires CO2 and reducing equivalents it is converted to formylmethanofuran with the formyl group residing at the aminomethyl group of the furan ring. • Transfer of the C1 moiety to tetrahydromethanopterin and reduction of the formyl to methyl group follows. • It is finally transferred to the Coenzyme M and is reduced to CH3 by the enzyme methyl co enzyme M methylreductase.
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  Formation of methanefrom bicarbonate • The four steps leading to formation of methane from bicarbonate are as follows HCO3- + H2 → HCOO- + H2O HCOO- + H2 + H+ → CH2O + H2O CH2O + H2 → CH3OH CH3OH + H2 → CH4 + H2O HCO3 + H+ + 4H2 → CH4 + 3H2O • The fourth step is coupled to the generation of proton motive force at the membrane which in turn is used by an ATP synthase for the phosphorylation of ADP to produce ATP. • Eg. Methanosarcina barkeri
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  Formation of methanefrom Acetate • Methanosarcina barkeri is a classic and representative species for those methanogenic bacteria that utilize acetate, methanol and methylamine as substrates. • Formation of methane from acetate is a oxidoreduction process. • First CO and methyl coenzyme M are produced which is the precursor for methane. CO2 is also produced.
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  Formation of methanefrom Methanol and Methylamine Methanogenesis of methanol and methylamine can be subdivided into two processes: • Oxidation of one fourth of the methyl groups to CO2 • Reduction of three fourth methyl groups to CH4. • A methanol:coenzyme M and a trimethylamine:coenzyme M methyltransferase have been characterized. • The methyl group is first transferred to the protein bound 5 hydroxy benzimidazolylcobamide. • Methyl groups transfer further proceeds to coenzyme M.