Major surface protein 1a effects tick infection and transmission of Anaplasma marginale.

Anaplasma marginale, an ehrlichial pathogen of cattle and wild ruminants, is transmitted biologically by ticks. A developmental cycle of A. marginale occurs in a tick that begins in gut cells followed by infection of salivary glands, which are the site of transmission to cattle. Geographic isolates of A. marginale vary in their ability to be transmitted by ticks. In these experiments we studied transmission of two recent field isolates of A. marginale, an Oklahoma isolate from Wetumka, OK, and a Florida isolate from Okeechobee, FL, by two populations of Dermacentor variabilis males obtained from the same regions. The Florida and Oklahoma tick populations transmitted the Oklahoma isolate, while both tick populations failed to transmit the Florida isolate. Gut and salivary gland infections of A. marginale, as determined by quantitative PCR and microscopy, were detected in ticks exposed to the Oklahoma isolate, while these tissues were not infected in ticks exposed to the Florida isolate. An adhesion-recovery assay was used to study adhesion of the A. marginale major surface protein (MSP) 1a to gut cells from both tick populations and cultured tick cells. We demonstrated that recombinant Escherichia coli expressing Oklahoma MSP1a adhered to cultured and native D. variabilis gut cells, while recombinant E. coli expressing the Florida MSP1a were not adherent to either tick cell population. The MSP1a of the Florida isolate of A. marginale, therefore, was unable to mediate attachment to tick gut cells, thus inhibiting salivary gland infection and transmission to cattle. This is the first report of MSP1a being responsible for effecting infection and transmission of A. marginale by Dermacentor spp. ticks. The mechanism of tick infection and transmission of A. marginale is important in formulating control strategies and development of improved vaccines for anaplasmosis.     

Genetic evidence against a morphologically suggestive conspecificity of Dermacentor reticulatus and D. marginatus (Acari: Ixodidae)

Dermacentor reticulatus and D. marginatus exhibit overlapping phenotypes. The possibility of conspecificity was investigated on the nucleotide level by comparing DNA sequences of the second internal transcribed spacer (ITS 2) of the rDNA gene. The inter-specific polymorphism was more than 20-times greater than the intra-specific polymorphism of 3 D. reticulatus strains of different geographic origins. Furthermore, the degree of polymorphisms between D. reticulatus and D. marginatus was found to be of the same order of magnitude as that between D. andersoni and D. variabilis, for which separate species status is accepted. These genomic findings do not support a possible conspecificity of D. reticulatus and D. marginatus.     

Purification and characterization of the lysozyme from the gut of the soft tick Ornithodoros moubata

The gut of the adult soft ticks Ornithodoros moubata displays high lytic activity against the bacteria Micrococcus luteus. The activity differed in the range of two orders of magnitude among individual animals and increased on average 4 fold during the first week following ingestion. In homogenates of first instar nymphs the activity was much lower increasing exponentially as nymphs neared the first molt. The protein responsible for this activity was purified out of gut contents of adult ticks by means of affinity adsorption on magnetic-chitin followed by two chromatography steps on cation exchange FPLC column MonoS. The homogeneous active protein has a mass of 14006 +/- 20 Daltons as determined by MALDI-TOF mass spectrometry. The N-terminal amino-acid sequence of this protein is K-V-Y-D-R-C-S-L-A-S-E-L-R with the highest similarity to the lysozyme from liver of rainbow trout and to lysozymes from digestive tracts of several mammals. The motif DRCSLA is specific for the digestive lysozymes of several dipteran insects. Based on this evidence, we have identified the protein as the tick gut lysozyme. The tick gut lysozyme has a pI near 9.7 and retains its full activity after treatment at 60 degrees C for 30 minutes. The pH optimum of the tick lysozyme was in the range from pH 5-7. Only marginal activity could be detected at pH > 8 which raises the question about the function of lysozyme in anti-bacterial defense in the environment of the tick gut.     

Identification and expression analysis of three c-type lysozymes in Oreochromis aureus

Lysozyme is an important molecule of innate immune system for the defense against bacterial infections. Three genes encoding chicken-type (c-type) lysozymes, C1-, C2-, C3-type, were obtained from tilapia Oreochromis aureus by RT-PCR and the RACE method. Catalytic and other conserved structure residues required for functionality were identified. The amino acid sequence identities between C1- and C2-type, C1- and C3-type, C2- and C3-type were 67.8%, 65.7% and 63.9%, respectively. Phylogenetic tree analyze indicated the three genes were firstly grouped to those of higher teleosteans, Pleuronectiformes and Tetraodontiformes fishes, and then clustered to those of lower teleosteans, Cypriniformes fishes. Bioinformatic analysis of mature peptide showed that the three genes possess typical sequence characteristics, secondary and tertiary structure of c-type lysozymes. The three tilapia c-type lysozymes mRNAs were mainly expressed in liver and muscle, and C1-type lysozyme also highly expressed in intestine. C1-type lysozyme mRNA was weakly expressed in stomach, C2- and C3-type mRNAs were weakly expressed in intestine. After bacterial challenge, up-regulation was obvious in kidney and spleen for C1-type lysozyme mRNA, while for C2- and C3-type lysozyme obvious increase were observed in stomach and liver, suggesting that C1-type lysozyme may mainly play roles in defense, while C2- and C3-type lysozyme mainly conduct digestive function against bacteria infection. All the three c-type recombinant lysozymes displayed lytic activity against Gram-negative and Gram-positive bacteria. These results indicated that three c-type lysozymes play important roles in the defense of O. aureus against bacteria infections.     

Molecular cloning and characterization of three novel lysozyme-like genes, predominantly expressed in the male reproductive system of humans, belonging to the c-type lysozyme/alpha-lactalbumin family

Lysozymes, especially c-type lysozymes, are well-recognized bacteriolytic factors widely distributed in the animal kingdom and play a mainly protective role in host defense. The relatives of c-type lysozymes, alpha-lactalbumins, however, are only found in mammalian milk and possess a distinct biological function. These two proteins, having similar amino acid sequences, gene structure, and dimensional conformation, belong to the c-type lysozyme/alpha-lactalbumin family. Using human lysozyme as an information probe, we cloned four human cDNAs encoding homologues of human lysozyme; these were named LYZL2, LYZL4, LYZL6, and SPACA3 by the HUGO Gene Nomenclature Committee. Of these four, SPACA3 has been reported to code an intra-acrosomal sperm protein SLLP1. To our knowledge, the other three are reported here for the first time. Using Northern blot hybridization, including 16 different human tissues, we found that these four lysozyme-like genes were all highly expressed in the testis/epididymis. Further analysis of one, LYZL4, by in situ hybridization revealed that its mRNA was only detected in the epithelium of human epididymis, most abundantly in the caput, suggesting that LYZL4 plays a physiological role in male reproduction. By sequence analysis, we found that two essential catalytic residues of the human lysozyme were conserved in LYZL2 and LYZL6, whereas one site in LYZL4 and two sites in SPACA3 were replaced. The LYZL2, LYZL4, LYZL6, and SPACA3 genes were mapped to human chromosome 10p11.23, 3p21.33, 17q11.2, and 17q12, respectively, and displayed a similar genomic structure. Our data suggest that these four lysozyme-like genes, which have arisen from a common progenitor gene, play a major role in human reproduction.     

Differential protein expression in ovaries of uninfected and Babesia-infected southern cattle ticks, Rhipicephalus (Boophilus) microplus

We used gel electrophoresis and mass spectrometry to investigate differences in protein expression in ovarian tissues from Babesia bovis-infected and uninfected southern cattle tick, Rhipicephalus (Boophilus) microplus. Soluble and membrane proteins were extracted from ovaries of adult female ticks, and analyzed by isoelectric focusing (IEF) and one-dimensional or two-dimensional (2-D) gel electrophoresis. Protein patterns were analyzed for differences in expression between infected and uninfected ticks. 2-D separation of proteins revealed a number of proteins that appeared to be up- or down-regulated in response to infection with Babesia, in particular membrane/membrane-associated proteins and proteins in a low molecular mass range between 6 and 36 kDa. A selection of differentially expressed proteins was subjected to analysis by capillary-HPLC-electrospray tandem mass spectrometry (HPLC-ESI-MS/MS). Among the ovarian proteins that were up-regulated in infected ticks were calreticulin, two myosin subunits, an endoplasmic reticulum protein, a peptidyl-prolyl cis–trans isomerase (PPIase), a cytochrome c oxidase subunit, a glutamine synthetase, and a family of Kunitz-type serine protease inhibitors. Among the down-regulated ovarian proteins were another PPIase, a hemoglobin subunit, and a lysozyme. This study is part of an ongoing effort to establish a proteome database that can be utilized to investigate specific proteins involved in successful pathogen transmission.     

Cloning and expression analysis of c-type and g-type lysozymes in yellow catfish (<Emphasis Type="Italic">Pelteobagrus fulvidraco</Emphasis>)

Lysozymes have important roles in innate immune system. Here, a c-type and a g-type lysozyme were identified from yellow catfish (Pelteobagrus fulvidraco). The deduced amino acid sequences of both lysozymes were conserved in catalytic sites and structural features as compared to their counterparts from other species. It was interesting that the g-type lysozyme possessed a signal peptide. The c-type and g-type lysozymes had the highest identity 89.4 and 76.2 % with that from channel catfish respectively. Phylogenetic analysis showed that the two lysozymes had a closely relationship with that from channel catfish and Astyanax mexicanus. Lysozymes from one order could form more than one clade in the phylogenetic tree, which indicated the gene duplications in evolution. Expression analysis with real time quantitative PCR revealed that the two lysozyme genes were constitutively expressed in all the tested tissues. The highest expression of c-type lysozyme was observed in liver, followed by spleen, head kidney, and trunk kidney, while the g-type lysozyme had highest expression in intestine, followed by spleen, head kidney, and trunk kidney. The mRNA levels of both genes were all up-regulated after challenging with Aeromonas hydrophila. However, there were differences in tissues and time points when the mRNA levels reached its peak between the two lysozymes. It indicated the diversity in regulation mechanisms and detailed functions among lysozymes. Taking together, these results will benefit the understanding of yellow catfish lysozymes.     

Thermal stability and enzymatic activity of a smaller lysozyme from silk moth (Bombyx mori)

Bombyx mori lysozyme is 10 amino acids shorter than hen egg-white lysozyme, which is a typical c-type lysozyme. It was expressed by using the methylotrophic yeast Pichia pastoris. The thermal stability and the enzymatic activity of the Bombyx mori lysozyme were estimated and compared with those of human and hen egg-white lysozymes. The denaturation temperature was 17-26°C lower than those of human and hen egg-white lysozymes. Further, the enthalpy change and the heat capacity change for unfolding were smaller than those of human lysozyme. It was also confirmed that the stability against guanidine hydrochloride was lower than those of the other two lysozymes. The enzymatic activity toward a simple synthetic substrate was measured and compared with those of human and hen egg-white lysozymes. The B-F binding mode was obviously dominant, although the A-E binding mode was preferred in human and hen egg-white lysozymes.     

BmiGI: a database of cDNAs expressed in Boophilus microplus, the tropical/southern cattle tick

We used an expressed sequence tag approach to initiate a study of the genome of the southern cattle tick, Boophilus microplus. A normalized cDNA library was synthesized from pooled RNA purified from tick larvae which had been subjected to different treatments, including acaricide exposure, heat shock, cold shock, host odor, and infection with Babesia bovis. For the acaricide exposure experiments, we used several strains of ticks, which varied in their levels of susceptibility to pyrethroid, organophosphate and amitraz. We also included RNA purified from samples of eggs, nymphs and adult ticks and dissected tick organs. Plasmid DNA was prepared from 11,520 cDNA clones and both 5' and 3' sequencing performed on each clone. The sequence data was used to search public protein databases and a B. microplus gene index was constructed, consisting of 8270 unique sequences whose associated putative functional assignments, when available, can be viewed at the TIGR website (http://www.tigr.org/tdb/tgi). A number of novel sequences were identified which possessed significant sequence similarity to genes, which might be involved in resistance to acaricides.     

Lyzl4, a novel mouse sperm-related protein, is involved in fertilization

The role of Chicken-type (c-type) lysozyme, a prototype lysozyme, in immunity has been characterized in many organisms. In this study, we cloned a novel c-type lysozyme-like gene, Lyzl4, which was located on mouse chromosome 9F4 and encoded 145 amino acids with a putative signal peptide and a protease cleavage site. The mature recombinant Lyzl4 protein expressed in yeast did not show the bacteriolytic activity. Sequence alignment analysis demonstrated that 3 of the 20 invariant residues in c-type lysozymes were changed in Lyzl4. One of the 'changed' amino acids (D52G) is located in the catalytic domain. Lyzl4 mRNA was selectively expressed in testis and epididymis in adult mice, with varying expression level across different developmental stages. High level of Lyzl4 protein was found on the spermatozoa of acrosomal region and principal piece of tail. Immuno-neutralization of Lyzl4 protein in spermatozoa with its specific antibody significantly decreased in vitro fertilization percentage in a dose-dependent manner, suggesting that Lyzl4 might be important for fertilization.     

Functional genomic studies of tick cells in response to infection with the cattle pathogen, Anaplasma marginale

The coevolution of ticks and the pathogens that they transmit has ensured their mutual survival. In these studies, we used a functional genomics approach to characterize tick genes regulated in response to Anaplasma marginale infection. Differentially regulated genes/proteins were identified by suppression-subtractive hybridization and differential in-gel electrophoresis analyses of cultured IDE8 tick cells infected with A. marginale. Nine of 17 of these genes were confirmed by real-time RT-PCR to be differentially regulated in ticks and/or IDE8 tick cells in response to A. marginale infection. RNA interference was used for functional studies. Six genes, which encode putative selenoprotein W2a, hematopoietic stem/progenitor cells protein-like, proteasome 26S subunit, ferritin, GST, and subolesin control, were found to affect A. marginale infection in IDE8 tick cells. Four genes, which encode putative GST, salivary selenoprotein M, vATPase, and ubiquitin, affected A. marginale infection in different sites of development in ticks. The results of these studies demonstrated that a molecular mechanism occurs by which tick cell gene expression mediates the A. marginale developmental cycle and trafficking through ticks.     

Cloning of cDNAs and hybridization analysis of lysozymes from two oyster species, Crassostrea gigas and Ostrea edulis

In bivalve molluscs including oysters, lysozymes play an important role in the host defense mechanisms against invading microbes. However, it remains unclear in which sites/cells the lysozyme genes are expressed and which subsequently produced the enzyme. This study cloned lysozyme cDNAs from the digestive organs of Pacific oyster Crassostrea gigas and European flat oyster Ostrea edulis. Both complete sequences of two oysters' lysozymes were composed of 137 amino acids. Two translated proteins present a high content in cysteine residues. Phylogenetic analyses showed that these oysters' lysozymes clustered with the invertebrate-type lysozymes of other bivalve species. In the Pacific oyster, lysozyme mRNA was expressed in all tissues except for those of the adductor muscle. In situ hybridization analyses revealed that lysozyme mRNA was expressed strongly in basophil cells in the digestive gland tubule of C. gigas, but not in digestive cells. Results indicated that the basophil cells of the oyster digestive gland are the sites of lysozyme synthesis.     

Molecular cloning of a phospholipid-hydroperoxide glutathione peroxidase gene from the tick, Boophilus microplus (Acari: Ixodidae)

Phospholipid-hydroperoxide glutathione peroxidase (PHGPx) enzymes are associated with cellular protection by the role they play in reducing hydroperoxides of phospholipids, thereby preventing membrane lipoperoxidation. As part of their toxic effect, some pesticides stimulate peroxidation of cellular membranes. We isolated and sequenced a PHGPx gene from the cattle tick Boophilus microplus that encodes a protein of 169 amino acids, including a TGA-encoded selenocysteine at residue 46 and active site residues Gln⁸² and Trp¹³⁵ that interact with the selenocysteine. The motif that directs the insertion of selenocysteine at the opal codon is found in the 3′-untranslated region. PHGPx sequences from pesticide-resistant and susceptible B. microplus ticks show nucleotide differences at eight positions among the strains, with five resulting in amino acid substitutions in the deduced protein sequence. Two distinct PHGPx alleles were identified in an organophosphate-resistant tick strain. Real-time PCR quantification of gene expression revealed increased PHGPx in two strains resistant to a single acaricide class. Strains resistant to two or more classes showed a reduction in PHGPx.     

Crystal structures of pheasant and guinea fowl egg-white lysozymes.

The crystal structures of pheasant and guinea fowl lysozymes have been determined by X-ray diffraction methods. Guinea fowl lysozyme crystallizes in space group P6(1)22 with cell dimensions a = 89.2 A and c = 61.7 A. The structure was refined to a final crystallographic R-factor of 17.0% for 8,854 observed reflections in the resolution range 6-1.9 A. Crystals of pheasant lysozyme are tetragonal, space group P4(3)2(1)2, with a = 98.9 A, c = 69.3 A and 2 molecules in the asymmetric unit. The final R-factor is 17.8% to 2.1 A resolution. The RMS deviation from ideality is 0.010 A for bond lengths and 2.5 degrees for bond angles in both models. Three amino acid positions beneath the active site are occupied by Thr 40, Ile 55, and Ser 91 in hen, pheasant, and other avian lysozymes, and by Ser 40, Val 55, and Thr 91 in guinea fowl and American quail lysozymes. In spite of their internal location, the structural changes associated with these substitutions are small. The pheasant enzyme has an additional N-terminal glycine residue, probably resulting from an evolutionary shift in the site of cleavage of prelysozyme. In the 3-dimensional structure, this amino acid partially fills a cleft on the surface of the molecule, close to the C alpha atom of Gly 41 and absent in lysozymes from other species (which have a large side-chain residue at position 41: Gln, His, Arg, or Lys). The overall structures are similar to those of other c-type lysozymes, with the largest deviations occurring in surface loops. Comparison of the unliganded and antibody-bound models of pheasant lysozyme suggests that surface complementarity of contacting surfaces in the antigen-antibody complex is the result of local, small rearrangements in the epitope. Structural evidence based upon this and other complexes supports the notion that antigenic variation in c-type lysozymes is primarily the result of amino acid substitutions, not of gross structural changes.