3.1.1.14	4-hydroxymercuribenzoate	-	970	
3.1.1.14	concanavalin A	-	2045	
3.1.1.14	Cu2+	-	19	
3.1.1.14	diisopropyl fluorophosphate	-	244	
3.1.1.14	Fe2+	-	25	
3.1.1.14	Fe3+	-	70	
3.1.1.14	Hg2+	-	33	
3.1.1.14	iodoacetamide	-	67	
3.1.1.14	Mg2+	-	6	
3.1.1.14	N-ethylmaleimide	-	49	
3.1.1.14	NEM	-	89	
3.1.1.14	PCMB	-	78	
3.1.1.14	phenylmethanesulfonyl fluoride	-	827	
3.1.1.14	phytol	-	2351	
3.1.1.14	Triton X-100	-	61	
3.1.1.14	Zn2+	-	14	
3.1.1.14	Mg2+	12% inhibition at 0.01 mM, 24 h preincubation	6	
3.1.1.14	Fe3+	13% inhibition at 0.01 mM, 24 h preincubation	70	
3.1.1.14	N-ethylmaleimide	13% inhibition at 1 mM, 24 h preincubation	49	
3.1.1.14	ferricyanide	2 mM, 17% inhibition	132	
3.1.1.14	refined bleached deodorized canola oil	20%	129627	
3.1.1.14	Hg2+	20% residual activity at 10 mM	33	
3.1.1.14	Hg2+	22% residual activity at 10 mM	33	
3.1.1.14	Hg2+	25% residual activity at 10 mM	33	
3.1.1.14	Fe2+	29% residual activity at 10 mM	25	
3.1.1.14	Fe2+	31% residual activity at 10 mM	25	
3.1.1.14	Cu2+	34% residual activity at 10 mM	19	
3.1.1.14	Fe2+	35% residual activity at 10 mM	25	
3.1.1.14	Cu2+	39% residual activity at 10 mM	19	
3.1.1.14	Cu2+	42% residual activity at 10 mM	19	
3.1.1.14	Al3+	49% residual activity at 10 mM	264	
3.1.1.14	Zn2+	51% residual activity at 10 mM	14	
3.1.1.14	Al3+	52% residual activity at 10 mM	264	
3.1.1.14	Bi3+	52% residual activity at 10 mM	15661	
3.1.1.14	Zn2+	54% residual activity at 10 mM	14	
3.1.1.14	Cu2+	55% inhibition at 0.01 mM, 24 h preincubation	19	
3.1.1.14	Bi3+	55% residual activity at 10 mM	15661	
3.1.1.14	Co2+	56% inhibition at 0.01 mM, 24 h preincubation	23	
3.1.1.14	Al3+	56% residual activity at 10 mM	264	
3.1.1.14	Bi3+	58% residual activity at 10 mM	15661	
3.1.1.14	phenylmethylsulfonyl fluoride	58% residual activity at 10 mM	257	
3.1.1.14	Zn2+	59% residual activity at 10 mM	14	
3.1.1.14	Zn2+	60% inhibition at 0.01 mM, 24 h preincubation	14	
3.1.1.14	phenylmethylsulfonyl fluoride	65% residual activity at 10 mM	257	
3.1.1.14	Mn2+	67% inhibition at 0.01 mM, 24 h preincubation	11	
3.1.1.14	phenylmethylsulfonyl fluoride	69% residual activity at 10 mM	257	
3.1.1.14	diethyldicarbonate	70% residual activity at 10 mM	310	
3.1.1.14	Fe3+	71% residual activity at 10 mM	70	
3.1.1.14	Co2+	72% residual activity at 10 mM	23	
3.1.1.14	diethyldicarbonate	72% residual activity at 10 mM	310	
3.1.1.14	Mn2+	72% residual activity at 10 mM	11	
3.1.1.14	Fe3+	73% residual activity at 10 mM	70	
3.1.1.14	Mn2+	73% residual activity at 10 mM	11	
3.1.1.14	Co2+	75% residual activity at 10 mM	23	
3.1.1.14	Co2+	78% residual activity at 10 mM	23	
3.1.1.14	Fe3+	78% residual activity at 10 mM	70	
3.1.1.14	Mn2+	78% residual activity at 10 mM	11	
3.1.1.14	Ag+	82% residual activity at 10 mM	75	
3.1.1.14	diethyldicarbonate	83% residual activity at 10 mM	310	
3.1.1.14	Hg2+	85% inhibition at 0.01 mM, 24 h preincubation	33	
3.1.1.14	Ag+	85% residual activity at 10 mM	75	
3.1.1.14	Fe2+	89% inhibition at 0.01 mM, 24 h preincubation	25	
3.1.1.14	Ag+	89% residual activity at 10 mM	75	
3.1.1.14	4-hydroxymercuribenzoate	93% inhibition at 1 mM, 24 h preincubation	970	
3.1.1.14	acetone	activates at lower concentration, Chlase2 reaches its maximal activity in 40% acetone, in 40-60% acetone the activity is reduced, overview	333	
3.1.1.14	sulfoquinovosyldiacylglycerol	and phosphatidyl glycerol, inactivation in a cooperative manner	97196	
3.1.1.14	phosphatidyl glycerol	and sulfoquinovosyldiacylglycerol, inactivation in a cooperative manner	20850	
3.1.1.14	Mg2+	eliminates the activating effect of lecithin	6	
3.1.1.14	Eupergit C	immobilization support	129628	
3.1.1.14	Eupergit C/EDA	immobilization support	129629	
3.1.1.14	beta-carotene	in absence of other lipids, inhibits chlorophyl a conversion	858	
3.1.1.14	phytol	in methanol, hydrolysis of chlorophyll a	2351	
3.1.1.14	additional information	inhibitory effects on recombinant enzymes purified by microtiter plate method and by affinity chromatography, respectively, overview, no inhibition by iodoacetic acid, iodoacetamide, 2-mercaptoethanol, and DTT	2	
3.1.1.14	levulinic acid	inhibits the chlorophyll synthesis in greening leaves, alters the chlorophyll a/chlorophyll b ratio	8266	
3.1.1.14	N-ethylmaleimide	irreversible, 15.9% inhibition at 10 mM, 1 h preincubation at pH 7.0 and 30°C	49	
3.1.1.14	iodoacetamide	irreversible, 6% inhibition at 10 mM, 1 h preincubation at pH 7.0 and 30°C	67	
3.1.1.14	PMSF	irreversible, 89.2% inhibition at 10 mM, 1 h preincubation at pH 7.0 and 30°C	248	
3.1.1.14	diisopropyl fluorophosphate	irreversible, 91% inhibition at 10 mM, 1 h preincubation at pH 7.0 and 30°C	244	
3.1.1.14	PCMB	irreversible, 92.6% inhibition at 1 mM, 1 h preincubation at pH 7.0 and 30°C	78	
3.1.1.14	Melatonin	melatonin treatment of seeds enhances the ability of pea seedlings to accelerate chlorophyll breakdown and chlorophyll de novo synthesis before stress by herbicide paraquat treatment appears and several hours after stressing, respectively, while during prolonged paraquat incubation, melatonin delays chlorophyll degradation	1536	
3.1.1.14	diisopropyl fluorophosphate	noncompeptitive	244	
3.1.1.14	additional information	poor inhibition by methyl methanethiosulfonate and iodoacetamide	2	
3.1.1.14	canola oil	presence of 10%, 20%, and 30% of canola oil decreased the activity of entrapped chlorophyllase by 60%, 75%, and 80%, respectively	66045	
3.1.1.14	Triton X-100	strong inhibition at 0.2-1.0%	61	
3.1.1.14	pheophytin b	substrate inhibition above 0.005 mM	12996	
3.1.1.14	additional information	the expression level and the activity of Chlase decrease significantly with the progress of the leaf-yellowing	2	
3.1.1.14	phytol	uncompetitive inhibition	2351