Fibrinogen-bearing protein genes in the snail Biomphalaria glabrata: Characterization of two novel genes and expression studies during ontogenesis and trematode infection

Zhang, Si-Ming; Nian, Hong; Zeng, Yong; DeJong, Randall J.

doi:10.1016/j.dci.2008.03.001

Cited by 49 publications

(38 citation statements)

References 45 publications

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“…FReDs from the snail Biomphalaria glabrata have been extensively studied in the past, 13,[44][45][46] and our observations are mainly confirmatory. Neighboring domains have previously been found to be immunoglobulin domains and, in one case, a brace of EGF domains.…”

Section: Non-chordatessupporting

confidence: 84%

“…Neighboring domains have previously been found to be immunoglobulin domains and, in one case, a brace of EGF domains. 46 The lengths of these FRePs range from 372 to 756 residues. One of these (NCBI: AEO50747.1) has a connector domain (COG1196) that is also found in a Drosophila FReP (NCBI: NP_001104020) and is a likely ortholog.…”

Section: Non-chordatesmentioning

confidence: 99%

“…12,13,[46][47][48]57,63,64 Chief among these are the ficolins. Although genes for ficolins have been found among the protochordates, notably they have not been found in fish.…”

Section: Freds and Innate Immunitymentioning

confidence: 99%

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Correlating structure and function during the evolution of fibrinogen‐related domains

2012

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Fibrinogen-related domains (FReDs) are found in a variety of animal proteins with widely different functions, ranging from non-self recognition to clot formation. All appear to have a common surface where binding of one sort or other occurs. An examination of 19 completed animal genomes-including a sponge and sea anemone, six protostomes, and 11 deuterostomeshas allowed phylogenies to be constructed that show where various types of FReP (proteins containing FReDs) first made their appearance. Comparisons of sequences and structures also reveal particular features that correlate with function, including the influence of neighbor-domains. A particular set of insertions in the carboxyl-terminal subdomain was involved in the transition from structures known to bind sugars to those known to bind amino-terminal peptides. Perhaps not unexpectedly, FReDs with different functions have changed at different rates, with ficolins by far the fastest changing group. Significantly, the greatest amount of change in ficolin FReDs occurs in the third subdomain (''P domain''), the very opposite of the situation in most other vertebrate FReDs. The unbalanced style of change was also observed in FReDs from nonchordates, many of which have been implicated in innate immunity.

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Section: Non-chordatessupporting

confidence: 84%

Section: Non-chordatesmentioning

confidence: 99%

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Correlating structure and function during the evolution of fibrinogen‐related domains

2012

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“…Thus, five CgFREPs could be divided into three subgroups with identity cutoff points of <86% [17]. Compared with subgroup 1 (CgFREP-2 and CgFREP-4), a 138 bp insertion existed in subgroup 2 (CgFREP-1 and CgFREP-3).…”

Section: Groups Of Frepsmentioning

confidence: 99%

Sequence variability of fibrinogen-related proteins (FREPs) in Crassostrea gigas

Zhang

2012

Chin. Sci. Bull.

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Fibrinogen-related proteins (FREPs) are lectins with at least a fibrinogen-like domain. They are widespread in Mollusca and play an important role as immune pattern-recognition receptors. These diverse molecules provide interesting models for the study of the evolution of innate immunity. Although oysters are among the most studied mollusks, there have been few investigations of this gene family in oysters. This paper reports the cloning of the first oyster FREP, named CgFREP, from the Pacific oyster Crassostrea gigas. Five types of FREP (CgFREP-1 to CgFREP-5) were obtained based on a single pair of primers, confirming their high diversity. The proteins deduced from these FREPs contained 253-363 amino acids and were divided into three subfamilies based on sequence identities (cutoff point <86%). The topological structure of the phylogenetic tree showed the five CgFREPs clustered together and were completely separated from the subgroup of FREPs obtained from Biomphalaria glabrata (BgFREPs). This implies that FREP diversity evolved before the BgFREPs branched off. An interesting aspect of the CgFREPs was their individual hypermutation. Ninety-three SNPs and five indels were characterized among CgFREPs. Some mutations (e.g. an insertion in CgFREP-5) could cause premature translation termination. Multiple alignments suggest recombination events might have occurred during exchanges between alleles, or by somatic diversification, or both. Individual sequence variability parallels the extraordinary complexity of the innate immune system, suggesting a potential capacity to recognize and eliminate many kinds of pathogens, even in a primitive system. The diversity of immune pattern-recognition receptors may offer an alternative strategy that functions in the absence of highly specific immune globulins, which only emerged in vertebrates. Crassostrea gigas, FREPs, fibrinogen-related proteins, recombination, oysters Citation:Zhang L L, Li L, Zhang G F. Sequence variability of fibrinogen-related proteins (FREPs) in Crassostrea gigas. Chin Sci Bull, 2012, 57: 33123319, doi: 10.1007/s11434-012-5155-6Maintenance of the immunological integrity of organisms is a driving force in evolution. A large number of heterogeneous non-self recognition strategies and defense mechanisms contribute to adaptive immunity. It is generally believed that only jawed vertebrates have a well-developed adaptive immune system. In contrast, innate immune mechanisms share similarities among invertebrates, vertebrates, and even plants [1,2]. Besides the rearrangement of immune globulin (IG) and T-cell receptor systems in adaptive immunity, another mechanism for the generation of immune diversity has emerged over the last several decades, i.

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“…FREPs from the snail Biomphalaria glabrata are composed of two functional domains, with an N-terminal immunoglobulin (Ig) domain that may be repeated in tandem and a C-terminal FBG domain (15,16,32,33). This family has at least 14 members, of which FREP2 is an immuneresponsive protein that plays a role in host-parasite interactions (34,35). A very recent interesting observation is that the FREPs demonstrated the recognition specificities to different categories of pathogens with FREP4 bound to parasites specifically (36).…”

mentioning

confidence: 99%

Anopheles Fibrinogen-related Proteins Provide Expanded Pattern Recognition Capacity against Bacteria and Malaria Parasites

Dong

Dimopoulos

2009

Journal of Biological Chemistry

172

157

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The fibrinogen-related protein family (FREP, also known as FBN) is an evolutionarily conserved immune gene family found in mammals and invertebrates. It is the largest pattern recognition receptor gene family in Anopheles gambiae, with as many as 59 putative members, while the Drosophila melanogaster genome has only 14 known FREP members. Our sequence and phylogenetic analysis suggest that this remarkable gene expansion in the mosquito is the result of tandem duplication of the fibrinogen domain. We found that the majority of the FREP genes displayed immune-responsive transcription after challenge with bacteria, fungi, or Plasmodium, and these expression patterns correlated strongly with gene phylogeny and chromosomal location. Using RNAi-mediated gene-silencing assays, we further demonstrated that some FREP members are essential factors of the mosquito innate immune system that are required for maintaining immune homeostasis, and members of this family have complementary and synergistic functions. One of the most potent anti-Plasmodium FREP proteins, FBN9, was found to interact with both Gram-negative and Gram-positive bacteria and strongly co-localized with both rodent and human malaria parasites in the mosquito midgut epithelium, suggesting that its defensive activity involves direct interaction with the pathogen. Interestingly, FBN9 formed dimers that bound to the bacterial surfaces with different affinities. Our findings indicate that the A. gambiae FREP gene family plays a central role in the mosquito innate immune system and provides an expanded pattern recognition and anti-microbial defense repertoire.

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Fibrinogen-bearing protein genes in the snail Biomphalaria glabrata: Characterization of two novel genes and expression studies during ontogenesis and trematode infection

Cited by 49 publications

References 45 publications

Correlating structure and function during the evolution of fibrinogen‐related domains

Correlating structure and function during the evolution of fibrinogen‐related domains

Sequence variability of fibrinogen-related proteins (FREPs) in Crassostrea gigas

Anopheles Fibrinogen-related Proteins Provide Expanded Pattern Recognition Capacity against Bacteria and Malaria Parasites

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