Biochemical studies of phenoloxidase and utilization of catecholamines in Cryptococcus neoformans

Protoplasts of Cryptococcus neoformans contain phenoloxidase as a membrane-bound enzyme. The enzyme appeared to be attached on the inner side of cytoplasmic membranes. Synthesis of the enzyme was derepressed by low levels of glucose but was not affected by the level of ammonium. Copper chelators which inhibited the phenoloxidase of other organisms did not affect cryptococcal enzymes. However, cyanide- or iron-chelating agents such as hydroximide derivates or 8-hydroxyquinoline were effective inhibitors, suggesting that cryptococcal phenoloxidase is an iron-containing enzyme. Phenoloxidase of C. neoformans catalyzed the oxidation of various diphenols via dopachrome and labile intermediates to melanin polymers. The kinetic constants (Km) of the phenoloxidase and the permease for dopamine and norepinephrine were low. The correlation between phenoloxidase and the preferential growth of C. neoformans in the host brain is discussed.     

Prophenoloxidase activation is not required for survival to microbial infections in Drosophila

The antimicrobial defence of Drosophila relies on cellular and humoral processes, of which the inducible synthesis of antimicrobial peptides has attracted interest in recent years. Another potential line of defence is the activation, by a proteolytic cascade, of phenoloxidase, which leads to the production of quinones and melanin. However, in spite of several publications on this subject, the contribution of phenoloxidase activation to resistance to infections has not been established under appropriate in vivo conditions. Here, we have isolated the first Drosophila mutant for a prophenoloxidase-activating enzyme (PAE1). In contrast to wild-type flies, PAE1 mutants fail to activate phenoloxidase in the haemolymph following microbial challenge. Surprisingly, we find that these mutants are as resistant to infections as wild-type flies, in the total absence of circulating phenoloxidase activity. This raises the question with regard to the precise function of phenoloxidase activation in defence, if any.     

On the latency and nature of phenoloxidase present in the left colleterial gland of the cockroach Periplaneta americana

The phenoloxidase system responsible for the sclerotization of cockroach ootheca is found to be present as an inactive form in the left colleterial gland of Periplaneta americana. The supernatant fraction obtained by centrifugation of the milky white secretions contained the inactive phenoloxidase which required both sodium dodecyl sulfate (SDS) and the insoluble sediment for exhibiting enzyme activity. Bovine serum albumin could replace the sediment in the activation process. Proteins separated from the supernatant fraction by molecular sieve chromatography on Sephadex G-25 did not require either albumin or the sediment, but required SDS for exhibiting the phenoloxidase activity. Among the detergents tested, SDS (anionic) and cetylpyridinium chloride (cationic) activated the phenoloxidase, but CHAPS (zwitterionic) or nonionic detergents failed to activate the enzyme. The activation caused by SDS occurred well below the critical micellar concentration of SDS indicating that SDS is causing the activation by binding to the protein and altering its conformation. Chloroform-methanol extracts of vestibulum or right gland could replace SDS confirming the presence of endogenous activator(s) of phenoloxidase system. A variety of exogenously added lipids could activate the latent enzyme, among which linoleate, oleate, laurate, linolenate, phosphatidylethanolamine, and phosphatidylglycerol proved to be the effective activators of the latent phenoloxidase. Partially purified phenoloxidase was found to be extremely labile and lost its activity on a) freezing and thawing, b) dialysis, and c) heating for 10 min at 55 degrees C. It exhibited a pH optimum of 7 and was inhibited drastically by phenylthiourea and diethyldithiocarbamate. It readily oxidized a number of o-diphenols such as 3,4-dihydroxybenzylalcohol, 3,4-dihydroxyphenethyl alcohol, catechol, N-acetyldopamine, N-acetylnorepinephrine, dopa, dopamine, etc., but failed to oxidize both 3,4-dihydroxybenzoic acid and 3,4-dihydroxybenzaldehyde. It neither converted the typical laccase substrate syringaldazine to its quinone methide product, nor oxidized the p-diphenols, hydroquinone and methylhydroquinone. Therefore, the enzyme participating in the quinone tanning of cockroach ootheca appears to be a typical o-diphenol oxidase and not a laccase as previously thought.     

Hemocyanin-derived phenoloxidase activity in the spiny lobster Panulirus argus (Latreille, 1804)

Hemocyanin and phenoloxidase belong to the type-3 copper protein family, sharing a similar active center whereas performing different roles. In this study, we demonstrated that purified hemocyanin (450 kDa) from the spiny lobster Panulirus argus shows phenoloxidase activity in vitro after treatment with trypsin, chymotrypsin and SDS (0.1% optimal concentration), but it is not activated by sodium perchlorate or isopropanol. The optimal pHs of the SDS-activated hemocyanin were 5.5 and 7.0. Hemocyanin from spiny lobster behaves as a catecholoxidase. Kinetic characterization using dopamine, L-DOPA and catechol shows that dopamine is the most specific substrate. Catechol and dopamine produced substrate inhibition above 16 and 2 mM respectively. Mechanism-based inhibition was also evidenced for the three substrates, being less significant for L-DOPA. SDS-activated phenoloxidase activity is produced by the hexameric hemocyanin. Zymographic analysis demonstrated that incubation of native hemocyanin with trypsin and chymotrypsin, produced bands of 170 and 190 kDa respectively, with intense phenoloxidase activity. Three polypeptide chains of 77, 80 and 89 kDa of hemocyanin monomers were identified by SDS-PAGE. Monomers did not show phenoloxidase activity induced by SDS or partial proteolysis.     

Electrophoretic study of the enzyme phenoloxidase from the enzyme gland in the foot of Perna viridis Linnaeus

The enzyme phenoloxidase from the enzyme gland in the foot of Perna viridis Linnaeus 1758 has been characterized electrophoretically. After fractionation, the gels were incubated in various phenolic substrates: catechol, Dopa, dopamine, hydroquinone, and tyrosine. The behavioural differences exhibited by phenoloxidase on incubation in different substrates have been discussed and compared with similar observations from insects. The occurrence of phenoloxidase in multiple forms has also been discussed.     

Ultrastructural localization of phenoloxidase in the midgut of refractory Anopheles gambiae and association of the enzyme with encapsulated Plasmodium cynomolgi

A melanogenic enzyme, phenoloxidase, was localized ultrastructurally in the midgut epithelia of 2 strains of Anopheles gambiae, a refractory strain that melanotically encapsulates Plasmodium cynomolgi ookinetes on the midgut, and a susceptible strain that does not. Midguts were incubated with either dopa or dopamine, and the resultant electron-dense product of phenoloxidase activity was localized on the basal lamina (BL) and cellular basal membrane labyrinth (BML) in uninfected mosquitoes of both strains. In infected refractory mosquitoes, the reaction products still were observed on the BL and BML but were especially dense in the BML of midgut cells near encapsulated ookinetes and in the capsule itself. In infected susceptible mosquitoes, phenoloxidase localization was reduced or absent in the BL and BML and was not observed near parasites. Phenylthiourea (PTU) inhibited the phenoloxidase reaction, indicating that the reaction product deposited in the absence of PTU resulted from enzyme activity and not autooxidation of the substrates. It is concluded that higher levels of phenoloxidase in the refractory strain following a blood meal may contribute to the ability to encapsulate ookinetes.     

Mosquito phenoloxidase and defensin colocalize in melanization innate immune responses.

Mosquitoes mount strong humoral and cellular immune responses against foreign organisms. Two components of the mosquito immune response that have received much attention are the phenoloxidase cascade that leads to melanization and antimicrobial peptides. The purpose of the current study was to use immunocytochemistry and transmission electron microscopy to identify the location of the melanization rate-limiting enzyme phenoloxidase and the antimicrobial peptide defensin in innate immune reactions against Escherichia coli and Micrococcus luteus by the mosquito Aedes aegypti. Our results show that both phenoloxidase and defensin are present at the sites of melanin biosynthesis in immune reactions against bacteria. Furthermore, both proteins are often present inside the same melanotic capsules. When hemocytes were analyzed, phenoloxidase was present in the cytosol of oenocytoids, but no significant amounts of defensin were detected inside any hemocytes. In summary, these data show that phenoloxidase and defensin colocalize in melanization reactions against bacteria and argue for further studies into the potential role of defensin in phenoloxidase-based melanization innate immune responses in mosquitoes.     

Hemocyanin-derived phenoloxidase activity in the spiny lobster Panulirus argus (Latreille, 1804)

Hemocyanin and phenoloxidase belong to the type-3 copper protein family, sharing a similar active center whereas performing different roles. In this study, we demonstrated that purified hemocyanin (450 kDa) from the spiny lobster Panulirus argus shows phenoloxidase activity in vitro after treatment with trypsin, chymotrypsin and SDS (0.1% optimal concentration), but it is not activated by sodium perchlorate or isopropanol. The optimal pHs of the SDS-activated hemocyanin were 5.5 and 7.0. Hemocyanin from spiny lobster behaves as a catecholoxidase. Kinetic characterization using dopamine, L-DOPA and catechol shows that dopamine is the most specific substrate. Catechol and dopamine produced substrate inhibition above 16 and 2 mM respectively. Mechanism-based inhibition was also evidenced for the three substrates, being less significant for L-DOPA. SDS-activated phenoloxidase activity is produced by the hexameric hemocyanin. Zymographic analysis demonstrated that incubation of native hemocyanin with trypsin and chymotrypsin, produced bands of 170 and 190 kDa respectively, with intense phenoloxidase activity. Three polypeptide chains of 77, 80 and 89 kDa of hemocyanin monomers were identified by SDS-PAGE. Monomers did not show phenoloxidase activity induced by SDS or partial proteolysis.     

Breeding for QX disease resistance negatively selects one form of the defensive enzyme, phenoloxidase, in Sydney rock oysters

QX disease in Sydney rock oysters (Saccostrea glomerata) is caused by the paramyxean protozoan, Marteilia sydneyi. Disease outbreaks occur during summer (January to May) and can result in up to 95% mortality. The New South Wales Department of Primary Industries has been selectively breeding S. glomerata for resistance to QX disease since 1996. Previous work suggests that this breeding program has specifically affected the defensive phenoloxidase enzyme system of oysters. The current study more thoroughly characterises the effect of selection on the different forms of phenoloxidase found in oyster populations. Native polyacrylamide gel electrophoresis (native-PAGE) identified five discrete types of phenoloxidase in non-selected (wild type) and fourth generation QX disease resistant (QXR4) oysters. One electrophoretically distinct form of phenoloxidase, POb, is significantly less frequent in resistant oysters when compared to the wild type population. The frequency of POb also decreased in both the wild type and QXR4 populations over the course of a QX disease outbreak. This suggests that possession of POb makes oysters susceptible to QX disease and that breeding for resistance has resulted in negative selection against this form of phenoloxidase.     

Attachment of phenoloxidase to fungal cell walls in arthropod immunity

In crayfish, phenoloxidase was located in the hemocytes. The plasma had infinitesimal enzyme activity. A phenoloxidase preparation from hemocytes precipitated spontaneously after approximately 1.5 hr at 22°C, which became attached spontaneously to glass, Plexiglas, and polystyrene plastic. The enzyme preparation could also become attached to Saccharomyces cerevisiae cell walls. Attachment was mediated by a proteinaceous substance, since trypsin significantly decreased the degree of attachment. Calcium ions were also necessary for attachment. A β-1,3-glucan, laminaran, partially prevented attachment to the fungal cell walls. Heparin caused precipitation of the phenoloxidase preparation from hemocytes. In crayfish cuticle, proteins with associated phenoloxidase activity were attached to cell walls of Aphanomyces astaci as well as to those of S. cerevisiae.     

Phenoloxidase in the ontogeny of Drosophila melanogaster

Electrophoretic spectrum of phenoloxidase was studied in 5 wild type and 17 mutant lines of D. melanogaster. Low-molecular alcohols (methanol, ethanol, and isopropanol) proved to be activators of the enzyme. Separate components of the phenoloxidase complex were activated by different agents. Electrophoretic spectrum of phenoloxidase was identical in larvae of 3rd age and 24-hour pupae. It consists of three fractions (A1, A2, and A3). Only the A1 fraction was seen on electrophoregrams of imago. No sex or age differences in phenoloxidase spectrum were observed during 25 days after birth. According to the A1 fraction polymorphism there were both normal and mutant genes coding for the A1 phenoloxidase subunit. The Dox-A1 gene that controls monophenoloxydase is located on the 2nd chromosome and is not linked with Dox-A2 and Dox-A3 genes coding for diphenoloxidases.     

Antifouling Bastadin Congeners Target Mussel Phenoloxidase and Complex Copper(II) Ions

Synthetically prepared congeners of sponge-derived bastadin derivatives such as 5,5′-dibromohemibastadin-1 (DBHB) that suppress the settling of barnacle larvae were identified in this study as strong inhibitors of blue mussel phenoloxidase that is involved in the firm attachment of mussels to a given substrate. The IC₅₀ value of DBHB as the most active enzyme inhibitor encountered in this study amounts to 0.84 μM. Inhibition of phenoloxidase by DBHB is likely due to complexation of copper(II) ions from the catalytic centre of the enzyme by the α-oxo-oxime moiety of the compound as shown here for the first time by structure activity studies and by X-ray structure determination of a copper(II) complex of DBHB.     

Oxidation of Phenolic Compounds by Mycobacterium leprae and Inhibition of Phenolase by Substrate Analogues and Copper Chelators

Experiments were conducted on the substrate specificity of phenoloxidase in Mycobacterium leprae, by using various phenolic compounds. Comparative studies were carried out with the enzyme from mammalian and plant sources. The phenolase of M. leprae was found to be similar to the enzyme of plant origin in oxidizing a variety of substrates; it was different from the mammalian enzyme, which has a limited substrate specificity. The findings confirmed that phenoloxidase is a specific property of M. leprae and is not a result of adsorption of host-tissue enzymes. The method used in separation of bacilli from infected tissues was evaluated for its effect on the viability of the organisms. This was tested by using M. lepraemurium as a model. The preparative procedure was found to have no adverse effect on the ability of the organisms to multiply in the mouse foot-pad. Several inhibitors of phenoloxidase have been tested-both substrate analogues and compounds which bind copper in the enzyme. Substances binding copper were found to be more effective. Since phenolase has been found to be a characteristic metabolic activity in M. leprae, nontoxic inhibitors of the enzyme offer possibilities of developing a rational chemotherapy of leprosy.     

Phenoloxidase activity in the hemolymph of the spiny lobster Panulirus argus

The prophenoloxidase activating system plays a major role in the defense mechanism of arthropods. In the present study, the phenoloxidase activity and its location in the hemolymph of the spiny lobster Panulirus argus is presented. Phenoloxidase activity was observed in the hemocyte lysate supernatant (HLS) and plasma after their incubation with trypsin. Higher amounts of trypsin were required to activate the HLS prophenoloxidase, due to the presence of a trypsin inhibitor in this fraction. Activation of prophenoloxidase was found when HLS was incubated with calcium, with an optimal pH between 7.5 and 8. This spontaneous activity is due to the prophenoloxidase activating enzyme, a serine proteinase that activates the prophenoloxidase once calcium ions were available. SDS was able to induce phenoloxidase activity in plasma and hemocyte fractions. Prophenoloxidase from HLS occurs as an aggregate of 300kDa. Electrophoretic studies combining SDS-PAGE and native PAGE indicate that different proteins produced the phenoloxidase activity found in HLS and plasma. Thus, as in most crustaceans, Panulirus argus contains a prophenoloxidase activating system in its hemocyte, comprising at least the prophenoloxidase activating enzyme and the prophenoloxidase. Finally, it is suggested that phenoloxidase activity found in plasma is produced by hemocyanin.     

Latent phenoloxidase activity and N-terminal amino acid sequence of hemocyanin from Bathynomus giganteus,a primitive crustacean

N-terminal amino acid sequences for the two hemocyanin subunits from the deep-sea crustacean Bathynomus giganteus have been determined by Edman degradation, providing the first sequence information for a hemocyanin from an isopod. In addition, purified hemocyanin from B. giganteus exhibited phenoloxidase activity in the presence of sodium dodecyl sulfate. Although a natural activator has not yet been identified, a preliminary study of the enzyme indicated a K(m) of 5mM for dopamine and an initial rate of 0.1 micromol per min per mg protein, values consistent with a significant role for this enzyme in the innate immune system of B. giganteus. Moreover, after separation of hemolymph by alkaline polyacrylamide gel electrophoresis, the only detectable phenoloxidase activity coincided with the two hemocyanin subunits. The hemocyanin of this primitive crustacean may fulfill dual functions, both as oxygen carrier and as the phenoloxidase crucial for host defense.     

棉铃虫感染中华卵索线虫后血淋巴酚氧化酶活性的变化及其分离纯化

研究了中华卵索线虫Ovomermis sinensis感染棉铃虫Helicoverpa armigera幼虫后宿主体内酚氧化酶活性的变化。研究结果表明,在感染后的第1天,中华卵索线虫的侵入引起酚氧化酶活性的增加,感染组酶活性是同期对照组的1.12倍; 但在随后的寄生期间,中华卵索线虫抑制了宿主的酚氧化酶活性,其中以第5天的抑制最为强烈： 同期对照组酶活性是感染组的1.52倍。对酚氧化酶进行了初步的分离纯化,纯化倍数为41.5倍,酶得率为12.7%,比活力为4 030.6 U/mg。     

棉铃虫不同虫态及虫龄血淋巴中酚氧化酶活力的比较

分别测定了棉铃虫Helicoverpa armigeraHübner不同虫态及虫龄血清和血细胞中酚氧化酶(phenoloxidase,PO)的活力。结果显示血清和血细胞中都有酚氧化酶活性,且血细胞中高于血清中。不同虫态及虫龄的血清和血细胞中酚氧化酶活力有很大的不同,血清和血细胞中酚氧化酶活力变化规律一致。3龄幼虫酶活力最高,5龄幼虫最低。酶活力大小依次为:3龄幼虫>预蛹>4龄幼虫>蛹>5龄幼虫     

Mutations in the sigma subunit of E. coli RNA polymerase which affect positive control of transcription

Summary An electrophoretic mobility variant of phenoloxidase in a lz stock of Drosophila melanogaster was identified as the A₃ component of the phenoloxidase complex by using two different activators to study enzyme activity — natural activator isolated from pupae and 50% 2-propanol. The structural gene for the A₃ proenzyme, Dox-3, was not associated with lz on the X chromosome; it mapped to the right of rdo (53.1) and left of M(2)m in the second linkage group.The lz locus affects the differentiation of the crystal cell, the type of hemocyte that carries prophenoloxidase(s) in paracrystalline form. Alleles of lz lacking paracrystalline inclusions in their hemocytes do not have phenoloxidase activity whereas alleles with paracrystalline inclusions have enzyme activity. The presence of proenzyme in the paracrystalline inclusions was demonstrated by in situ activation with natural activator or propanol followed by incubation in buffered dopa.     

Latent larval cuticular phenoloxidase in the coconut pest,Oryctes rhinoceros

Cuticular phenoloxidase (Tyrosinase) in the larval stage of the coconut pest Oryctes rhinoceros has been extracted in the stable proform using cane sugar saline/borate buffer. The extracted prophenol oxidase can be activated by the addition of proteolytic enzymes such as trypsin, chymotrypsin, thermolysin, and subtilisin. Detergents such as SDS and Tween-80 also activated the enzyme. Electrophoretical analysis revealed dissociation of the enzyme into two molecular forms after its activation by proteolytic enzymes. The functional significance of the enzyme is suggested to involve the generation of quinone compounds in the wound healing process: most phenoloxidase inhibitors prevented melanization when applied topically to surgical wounds. © 1996 Wiley-Liss, Inc.