176 BACTERIOLOGICAL AND ENZYME CHEMISTRY 



capable of oxidation to the substance known as oxiurushic 

 acid thus : 



2C 14 H 19 2 + 30 = 2C 14 H 18 3 + H 2 



Some ten years later Bertrand separated the juice into 

 laccol, an alcohol derivative which was soluble in alcohol, 

 and into the enzyme laccase which was insoluble in alcohol. 

 Laccol was found to oxidise spontaneously, but the rate 

 of oxidation was greatly accelerated when laccase was 

 present. 



An enzyme with the same properties was obtained from 

 many vegetables, especially members of the mushroom family. 

 The same enzyme also will oxidise numerous hydroxy and 

 amido derivatives of benzene to quinone : thus in the case of 

 hydroquinone the following reaction takes place : 



C 6 H 4 (OH) 2 + = = C 6 H 4 0, + H 2 



While the action of laccase, or an enzyme akin to it, is not 

 specific, in the sense that one reaction and one only can be 

 brought about by its intervention, yet it has its limitations, 

 and will only oxidise such bodies as are capable of yielding 

 quinols. It does not, therefore, oxidise tyrosin, the formula 

 of which, it may be remembered, is 



C 6 H 4 OHCH 2 CHNH 2 C0 2 H 



and which would therefore require to be broken up completely 

 before a quinol could result from its oxidation. Tyrosin can, 

 however, be oxidised by a specific enzyme known as tyrosinase, 

 which has quite recently been investigated by Gortner. The 

 source of Gortner's enzyme was the meal worm. To obtain 

 the enzyme the larvae were ground in a mortar with chloroform 

 water, and the milky liquid strained through a cheese cloth : the 

 milky extract if kept a short time in the air rapidly darkens 

 on the surface, it remains white where not in contact with 

 oxygen. It was found that a soluble and insoluble tyrosinase 



