Acidic chitinases (EC 3.2.1.14) were isolated and characterized from 4-week-old nonembryogenic Citrus sinensis L. Osbeck cv 'Valencia' callus tissue. The enzymes were purified using size exclusion, anion exchange, and chromatofocusing HPLC techniques. Eleven isoforms were isolated with M(r)s between 26,000 and 37,400. Eight of the isoforms were purified to homogeneity, and all but one cross-reacted with a polyclonal antibody raised against a basic class I potato leaf chitinase. The isoelectric points (determined by chromatofocusing) were from pH 4.5 to 5.4. All hydrolases degraded chitin and four were capable of hydrolyzing solubilized shrimp shell chitosan suggesting they may be chitosanases (EC 3.2.1.99). Apparent chitosanase activity generally decreased with decreasing acetylation of the chitosan (i.e. from 20% to 0% acetylation). The chitinases and chitinases/chitosanases are predominantly endochitinases. Chitosanase activity was optimal at pH 5 while the pH optimum for chitinase activity ranged between pH 3.5 and 5.5. The chitinases and chitinases/chitosanases were stable up to 60 degrees C and showed their highest enzyme activity at that temperature. N-terminal sequences were obtained on three of the isoforms. One of the isoforms was identified as a class II chitinase and the other two as class III chitinases.
Seven endochitinases (EC 3.2.1.14) (relative molecular masses 23,000-28,000 and isoelectric points 10.3-10.4) were purified from nonembryogenic Citrus sinensis L. Osbeck cv. Valencia callus tissue. The basic chitinase/lysozyme from this tissue (BCLVC) exhibited lysozyme, chitinase and chitosanase activities and was determined to be a class III chitinase. While BCLVC acted as a lysozyme at pH 4.5 and low ionic strength (0.03) it acted as a chitinase/chitosanase at high ionic strengths (0.2) with a pH optimum of ca. 5. The lysozyme activity of BCLVC was inhibited by histamine, imidazole, histidine and the N-acetyl-D-glucosamine oligosaccharide (GlcNAc)3. The basic chitinase from cv. Valencia callus, BCVC-2, had an N-terminal amino acid sequence similar to tomato and tobacco AP24 proteins. The sequences of the other five chitinases were N-terminal blocked. Whereas BCLVC was capable of hydrolyzing 13.8-100% acetylated chitosans and (GlcNAc)4-6 oligosaccharides, BCVC-2 hydrolyzed only 100% acetylated chitosan, and the remaining enzymes expressed varying degrees of hydrolytic capabilities. Experiments with (GlcNAc)2-6 suggest that BCLVC hydrolysis occurs in largely tetrasaccharide units whereas hydrolysis by the other chitinases occurs in disaccharide units. Cross-reactivities of the purified proteins with antibodies for a potato leaf chitinase (AbPLC), BCLVC, BCVC-3, and tomato AP24 indicate that these are separate and distinct proteins.
H. 1995. Citrus rootstock responses to herbivor>' by larvae of the sugarcane rootstock borer weevil {Diaprepes abhreviattts), -Physiol. Plant. 94: 164-173, The responses of roots to feeding by larvae of a citrus root weevii {Diaprepes abbreviatus) were investigated in Citrus grandis (L,) Osb. x Poncirus trifoliata (2N) (L.) Raf.; C. grandis x P. trifoliata (4N): P. rrifoliata x C, grandis (Flying Dragon x Nakon); C. paradisi Macf. x P. trifoliata (Swingle citrumelo}: C. aurantifolia (Christm.) Swingle (Citrus macrophyllaY, C. reticuiata Blanco (Cleopatra mandarin): C, sinensis (L.) Osb. x P. trifoliata (Carrizo citrange): C. aurantium (L.) (sour orange).Chitinase, chitosanase,/S-1,3-glucanase, peroxidase and lysozyme activities were measured and significant differences were observed for some of the cultivars between infested and uninfested rootstocks. Generally, increased activities were observed for chitinases and decrea,sed activities were observed for the other enzymes measured. Numerous significant differences in hydrolase and peroxidase activities were observed between cultivars. Immunologicai detection revealed that new protein bands occurred in root protein extracts for six of the eight cultivars infested with larvae when an antibody to a class 1 potato leaf chitina,se was used. Antibodies generated against two citrus chitinases of M, 24 000 (basic chitinase ev. Valencia (C. sinensis) callus, BCVC) and M, 28 (XX) (basic chitinase/lysozyme cv. Valencia callus, BCLVC) Indicated that chitinases in Carrizo were induced in infested roots when the BCVCT antibody was employed. These findings justify calling these proteins patbogenesis-related proteins. The chitinase that BCLVC was prepared from exhibited high lysozyme activities, and the results of western blots showed tbe presence of proteins at M, 24 000 and 27 000 which are presumed to be lysozymes. Similar tests using antibodies against /?-l,3glucanases and peroxidases indicated a diminution of protein bands that cross-reacted with infested root protein extracts compared with what occurred in controls. All of the root extracts were tested against chitosans with various percentages of acetylation: activities were linearly dependent on the amount of chitosan acetylation; i.e. tbe larger the amount of acetylation, the greater the activity. Significant differences in hydrolase activities were observed between infested and uninfested roots for the rootstocks using the variously acetylated substrates. All of the root protein extracts were capable of degrading peritrophic membranes removed from larvae of D. abhreviatus. This suggests that eitrus chitinases may play a role in disrupting the peritrophic membrane such that ingested substances that pose a hazard to the insect may penetrate the membrane more easily.
Marek’s Disease Virus (MDV) is a widespread α-herpesvirus of chickens that causes T cell tumors. Acute, but not latent, MDV infection has previously been shown to lead to downregulation of cell-surface MHC class I (Virology 282:198–205 (2001)), but the gene(s) involved have not been identified. Here we demonstrate that an MDV gene, MDV012, is capable of reducing surface expression of MHC class I on chicken cells. Co-expression of an MHC class I-binding peptide targeted to the endoplasmic reticulum (bypassing the requirement for the TAP peptide transporter) partially rescued MHC class I expression in the presence of MDV012, suggesting that MDV012 is a TAP-blocking MHC class I immune evasion protein. This is the first unique non-mammalian MHC class I immune evasion gene identified, and suggests that α-herpesviruses have conserved this function for at least 100 million years.
Marek's disease virus (MDV) is an oncogenic alphaherpesvirus of Gallus gallus, the domesticated chicken. Control strategies rely upon vaccination with live attenuated viruses of antigenically similar avian herpesviruses or attenuated strains of MDV. Recent studies in other viruses have shown that recoding certain viral genes to employ synonymous but rarely-used codon pairs resulted in viral attenuation. We deoptimized two MDV proteins, UL54/ICP27 and UL49/VP22, and demonstrate that the more severely deoptimized variant of UL54 accumulates significantly less gene product in vitro. Using these UL54 deoptimized mutants, we further demonstrate that animals infected with the UL54-recoded recombinant virus exhibited decreased viral genome copy number in lymphocytes, reduced lymphoid atrophy and reduced tumor incidence. This study demonstrates that codon pair deoptimization of a single viral gene can produce attenuated strains of MDV. This approach may be useful as a rational way of making novel live attenuated virus vaccines for MDV.
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