A DNA barcode library for mangrove gastropods and crabs of Hong Kong and the Greater Bay Area reveals an unexpected faunal diversity associated with the intertidal forests of Southern China.

BACKGROUND: Mangroves are tropical and subtropical intertidal forests colonising sheltered coasts across the world. They host a unique faunal community, dominated by brachyuran crabs and gastropods. These invertebrates strongly contribute to the functionality of the entire forest. The reliable assessment of mangrove faunal diversity is, thus, a crucial step for efficient management and conservation plans, but it is hindered by difficulties in species identification. Here we provide a verified DNA barcode library for brachyuran crabs and gastropods inhabiting the mangroves of the Greater Bay Area, Southern China. In particular, we collected and morphologically identified 1100 specimens of mangrove associated brachyuran crabs and gastropods. The partial sequences of the mtDNA cytochrome oxidase subunit I gene were obtained from 275 specimens. Barcode sequences were then used to delineate Molecular Operational Taxonomic Units (MOTUs), employing three different delimitation methods: the automatic barcode gap discovery (ABGD) method, the general mixed Yule coalescent (GMYC) model and a Bayesian implementation of the Poisson tree processes (bPTP) model. RESULTS: By integrating DNA barcodes with morphology, we identified 44 gastropod species and 58 brachyuran species associated with Hong Kong mangroves, with five and seven new records, for gastropods and crabs, respectively, for the Greater Bay Area. The delineation of MOTUs based on barcode sequences revealed a strong congruence between morphological and molecular identification for both taxa, showing the high reliability of the barcode library. CONCLUSIONS: This study provides the first reference barcode library for mangrove-associated macrobenthic fauna in the Greater Bay Area and represents a reliable tool to management and conservation plans. Our molecular analyses resolved long lasting taxonomic misidentifications and inconsistencies and updated the knowledge on the geographical distribution of Asian mangrove associated fauna, ultimately highlighting a level of biodiversity higher than previously thought for Southern China.

Immunisation with recombinant AMA-1 protects mice against infection with Plasmodium chabaudi.

The Plasmodium merozoite surface antigen apical membrane antigen-1 (AMA-1) has previously been shown to provide partial protection to Saimiri and rhesus monkeys immunised with recombinant Plasmodium fragile or parasite-derived Plasmodium knowlesi AMA-1, respectively. In the study reported here we have used the Plasmodium chabaudi/mouse model system to extend our pre-clinical assessment of an AMA-1 vaccine. We describe here the expression of the full-length Plasmodium chabaudi adami AMA-1 and the P. chabaudi adami AMA-1 ectodomain using both baculovirus and Escherichia coli. The ectodomain expressed in E. coli, which contained an N-terminal hexa-his tag, was purified by Ni-chelate chromatography and refolded in vitro in the presence of oxidised and reduced glutathione to generate intramolecular disulphide bonds. In a series of vaccine trials, in both inbred and outbred mice, highly significant protection was obtained by immunising with the refolded AMA-1 ectodomain. Protection was shown to correlate with antibody response and was dependent on intact disulphide bonds. Passive transfer of antibodies raised in rabbits against the refolded AMA-1 ectodomain was also protective. In view of this demonstration that E. coli expression of a soluble P. chabaudi AMA-1 domain can generate a vaccine that is effective in mice, we are pursuing a similar approach to generating a vaccine against P. falciparum for testing in human volunteers.

Autoantibodies to evolutionarily conserved epitopes of enolase in a patient with discoid lupus erythematosus.

Although the pathology of discoid lupus erythematosus is well documented the causative agents are not known. Here, we report the identity of the target antigen of an autoantibody present in high titre in the serum of a patient with discoid lupus erythematosus. We have demonstrated that the antigen is enolase; first, because it has properties consistent with this glycolytic enzyme (47,000 MW, cytosolic localization and ubiquitous tissue distribution). Secondly, limited amino acid sequence determination after trypsin digestion shows identity with alpha-enolase. Finally, the autoimmune serum immunoblots rabbit and yeast enolase and predominantly one isoelectric form of enolase (PI approximately 6.1). These results indicate that the reactive autoepitopes are highly conserved from man to yeast. The results also suggest that the autoantibodies are most reactive to the alpha-isoform of enolase, although it is possible that they may also be reactive with gamma-enolase, and have least reactivity to beta-enolase. The anti-enolase autoantibodies belong to the immunoglobulin G1 (IgG1) isotype. This is the first report of IgG1 autoantibodies to evolutionarily conserved autoepitopes of enolase in the serum of a patient with discoid lupus erythematosus. Previous reports of autoantibodies to enolase have suggested associations with autoimmune polyglandular syndrome type I and cancer-associated retinopathy. This report and an earlier report of what is likely to be enolase autoantibodies in two patients without systemic disease suggest that enolase autoantibodies have a broad association and are not restricted to any particular disease.

The disulfide bond structure of Plasmodium apical membrane antigen-1.

Apical membrane antigen-1 (AMA-1) of Plasmodium falciparum is one of the leading asexual blood stage antigens being considered for inclusion in a malaria vaccine. The ability of this molecule to induce a protective immune response has been shown to be dependent upon a conformation stabilized by disulfide bonds. In this study we have utilized the reversed-phase high performance liquid chromatography of dithiothreitol-reduced and nonreduced tryptic digests of Plasmodium chabaudi AMA-1 secreted from baculovirus-infected insect cells, in conjunction with N-terminal sequencing and electrospray-ionization mass spectrometry, to identify and assign disulfide-linked peptides. All 16 cysteine residues that are conserved in all known sequences of AMA-1 are incorporated into intramolecular disulfide bonds. Six of the eight bonds have been assigned unequivocally, whereas the two unassigned disulfide bonds connect two Cys-Xaa-Cys sequences separated by 14 residues. The eight disulfide bonds fall into three nonoverlapping groups that define three possible subdomains within the AMA-1 ectodomain. Although the pattern of disulfide bonds within subdomain III has not been fully elucidated, one of only two possible linkage patterns closely resembles the cystine knot motif found in growth factors. Sites of amino acid substitutions in AMA-1 that are well separated in the primary sequence are clustered by the disulfide bonds in subdomains II and III. These findings are consistent with the conclusion that these amino acid substitutions are defining conformational disulfide bond-dependent epitopes that are recognized by protective immune responses.

Protective immune responses to apical membrane antigen 1 of Plasmodium chabaudi involve recognition of strain-specific epitopes.

Apical membrane antigen 1 (AMA-1), an asexual blood-stage antigen of Plasmodium falciparum, is an important candidate for testing as a component of a malaria vaccine. This study investigates the nature of diversity in the Plasmodium chabaudi adami homolog of AMA-1 and the impact of that diversity on the efficacy of the recombinant antigen as a vaccine against challenge with a heterologous strain of P. chabaudi. The nucleotide sequence of the AMA-1 gene from strain DS differs from the published 556KA sequence at 79 sites. The large number of mutations, the nonrandom distribution of both synonymous and nonsynonymous mutations, and the nature of both the codon changes and the resulting amino acid substitutions suggest that positive selection operates on the AMA-1 gene in regions coding for antigenic sites. Protective immune responses induced by AMA-1 were strain specific. Immunization of mice with the refolded ectodomain of DS AMA-1 provided partial protection against challenge with virulent DS (homologous) parasites but failed to protect against challenge with avirulent 556KA (heterologous) parasites. Passive immunization of mice with rabbit antibodies raised against the same antigen had little effect on heterologous challenge but provided significant protection against the homologous DS parasites.