Localization of chlorophyllase in the chloroplast envelope

Chlorophyllase catalyzes the first step in the catabolic pathway of chlorophyll. It is a constitutive enzyme located in chloroplast membranes. In isolated plastids the hydrolysis of the endogenous chlorophyll does not take place unless the membranes are solubilized in the presence of detergent. The structural latency of chlorophyllase activity appears to be due to the differential locations of substrate and enzyme within the plastids. Envelope membranes prepared from both chloroplasts and gerontoplasts contain chlorophyllase activity. The isolation of envelopes is associated with a marked increase in chlorophyllase activity per unit of protein. Yields of chlorophyllase and of specific envelope markers in the final preparations are similar, suggesting that the enzyme may be located in the envelope. It is hypothesized that the breakdown of chlorophyll during leaf senescence requires a mechanism that mediates the transfer of chlorophyll from the thylakoidal pigment-protein complexes to the sites of catabolic reactions in the envelop

Altered patterns of senescence and ripening in gf, a stay-green mutant of tomato (Lycopersicon esculentum Mill.)

The gf tomato mutant, which retains chlorophyll during ripening, has been found to be affected in leaf senescence. The leaves of the gf mutant show an absolute stay-green phenotype. As leaf senescence and fruit ripening proceed, there is a marked difference in chlorophyll content between wild-type and gf. In both attached and detached leaf studies, or after treatment with ethylene, the leaves withered and abscised in gf with only slight loss of chlorophyll and carotenoids. Total protein content declined and free amino acids increased during leaf senescence in wild-type and gf, but Western analysis showed that LHCII polypeptides were retained at higher levels in gf. Expression of senescence-related mRNAs increased normally in gf whereas those for cab, rbcS and rbcL declined in both mutant and wild-type. The mutant possesses enzyme activity for chlorophyllase, the formation of phaeophorbide a by the action of Mg-dechelatase and the oxygenolytic opening of the porphyrin macrocycle. Analysis of chlorophyll breakdown products in fruit indicated that gf, like other stay-green mutants, accumulates chlorophyllides a and b, but phaeophorbide a does not accumulate in vivo. This may indicate that, in the mutant, in vivo the action of phaeophorbide a-oxygenase is somehow prevented, either by altered accessibility or transport of components required for thylakoid disassembly or the absence of another facto

Localization of chlorophyllase in the chloroplast envelope

Chlorophyllase catalyzes the first step in the catabolic pathway of chlorophyll. It is a constitutive enzyme located in chloroplast membranes. In isolated plastids the hydrolysis of the endogenous chlorophyll does not take place unless the membranes are solubilized in the presence of detergent. The structural latency of chlorophyllase activity appears to be due to the differential locations of substrate and enzyme within the plastids. Envelope membranes prepared from both chloroplasts and gerontoplasts contain chlorophyllase activity. The isolation of envelopes is associated with a marked increase in chlorophyllase activity per unit of protein. Yields of chlorophyllase and of specific envelope markers in the final preparations are similar, suggesting that the enzyme may be located in the envelope. It is hypothesized that the breakdown of chlorophyll during leaf senescence requires a mechanism that mediates the transfer of chlorophyll from the thylakoidal pigment-protein complexes to the sites of catabolic reactions in the envelop