Your search keyword '"Perner, Jan"' showing total 3 results

1. Inducible glutathione S-transferase (IrGST1) from the tick Ixodes ricinus is a haem-binding protein.

Author

Perner, Jan, Kotál, Jan, Hatalová, Tereza, Urbanová, Veronika, Bartošová-Sojková, Pavla, Brophy, Peter M., and Kopáček, Petr

Subjects

*GLUTATHIONE transferase, *CARRIER proteins, *CASTOR bean tick, *NUCLEOTIDE sequence, *ARGASIDAE

Abstract

Blood-feeding parasites are inadvertently exposed to high doses of potentially cytotoxic haem liberated upon host blood digestion. Detoxification of free haem is a special challenge for ticks, which digest haemoglobin intracellularly. Ticks lack a haem catabolic mechanism, mediated by haem oxygenase, and need to dispose of vast majority of acquired haem via its accumulation in haemosomes. The knowledge of individual molecules involved in the maintenance of haem homeostasis in ticks is still rather limited. RNA-seq analyses of the Ixodes ricinus midguts from blood- and serum-fed females identified an abundant transcript of glutathione S-transferase ( gst ) to be substantially up-regulated in the presence of red blood cells in the diet. Here, we have determined the full sequence of this encoding gene, ir-gst1 , and found that it is homologous to the delta-/epsilon-class of GSTs. Phylogenetic analyses across related chelicerates revealed that only one clear Ir GST1 orthologue could be found in each available transcriptome from hard and soft ticks. These orthologues create a well-supported clade clearly separated from other ticks' or mites’ delta-/epsilon-class GSTs and most likely evolved as an adaptation to tick blood-feeding life style. We have confirmed that Ir GST1 expression is induced by dietary haem(oglobin), and not by iron or other components of host blood. Kinetic properties of recombinant Ir GST1 were evaluated by model and natural GST substrates. The enzyme was also shown to bind haemin in vitro as evidenced by inhibition assay, VIS spectrophotometry, gel filtration, and affinity chromatography. In the native state, Ir GST1 forms a dimer which further polymerises upon binding of excessive amount of haemin molecules. Due to susceptibility of ticks to haem as a signalling molecule, we speculate that the expression of Ir GST1 in tick midgut functions as intracellular buffer of labile haem pool to ameliorate its cytotoxic effects upon haemoglobin intracellular hydrolysis. [ABSTRACT FROM AUTHOR]

Published

2018

2. From the fat body to the hemolymph: Profiling tick immune and storage proteins through transcriptomics and proteomics.

Author

Urbanová, Veronika, Lu, Stephen, Kalinová, Eliška, Martins, Larissa, Kozelková, Tereza, Dyčka, Filip, Ribeiro, José M., Hajdušek, Ondřej, Perner, Jan, and Kopáček, Petr

Subjects

*FAT, *TRANSCRIPTOMES, *TICK infestations, *HEMOLYMPH, *PROTEOMICS, *TICKS, *PLANT defenses

Abstract

Ticks are blood-feeding arachnids that are known to transmit various pathogenic microorganisms to their hosts. During blood feeding, ticks activate their metabolism and immune system to efficiently utilise nutrients from the host's blood and complete the feeding process. In contrast to insects, in which the fat body is known to be a central organ that controls essential metabolic processes and immune defense mechanisms, the function of the fat body in tick physiology is still relatively unexplored. To fill this gap, we sought to uncover the repertoire of genes expressed in the fat body associated with trachea (FB/Tr) by analyzing the transcriptome of individual, partially fed (previtellogenic) Ixodes ricinus females. The resulting catalog of individual mRNA sequences reveals a broad repertoire of transcripts encoding proteins involved in nutrient storage and distribution, as well as components of the tick immune system. To gain a detailed insight into the secretory products of FB/Tr specifically involved in inter-tissue transport and humoral immunity, the transcriptomic data were complemented with the proteome of soluble proteins in the hemolymph of partially fed female ticks. Among these proteins, the hemolipoglyco-carrier proteins were predominant. When comparing immune peptides and proteins from the fat body with those produced by hemocytes, we found that the fat body serves as a unique producer of certain immune components. Finally, time-resolved transcriptional regulation of selected immune transcripts from the FB/Tr was examined in response to experimental challenges with model microbes and analyzed by RT-qPCR. Overall, our data show that the fat body of ticks, similar to insects, is an important metabolic tissue that also plays a remarkable role in immune defense against invading microbes. These findings improve our understanding of tick biology and its impact on the transmission of tick-borne pathogens. [Display omitted] • The first transcriptomic study of the fat body/trachea (FB/Tr) complex of ticks was performed. • Transcriptomic data were complemented by proteomic analysis of the hemolymph. • Hemolipoglyco-carrier proteins (HeLp) produced in the FB/Tr complex were a predominant fraction of tick plasma. • Expression of FB/Tr transcripts encoding immune genes responded to microbial challenge. [ABSTRACT FROM AUTHOR]

Published

2024

3. Dual SIFamide receptors in Ixodes salivary glands.

Author

Guerrib, Fetta, Ning, Caina, Mateos-Hernandéz, Lourdes, Rakotobe, Sabine, Park, Yoonseong, Hajdusek, Ondrej, Perner, Jan, Vancová, Marie, Valdés, James J., and Šimo, Ladislav

Subjects

*SALIVARY glands, *IXODES, *IXODES scapularis, *CASTOR bean tick, *EPITHELIAL cells, *PEPTIDES

Abstract

Salivary glands are vital to tick feeding success and also play a crucial role in tick-borne pathogen transmission. In previous studies of Ixodes scapularis salivary glands, we demonstrated that saliva-producing type II and III acini are innervated by neuropeptidergic axons which release different classes of neuropeptides via their terminals (Šimo et al., 2009b, 2013). Among these, the neuropeptide SIFamide—along with its cognate receptor—were postulated to control the basally located acinar valve via basal epithelial and myoepithelial cells (Vancová et al., 2019). Here, we functionally characterized a second SIFamide receptor (SIFa_R2) from the I. scapularis genome and proved that it senses a low nanomolar level of its corresponding ligand. Insect SIFamide paralogs, SMYamides, also activated the receptor but less effectively compared to SIFamide. Bioinformatic and molecular dynamic analyses suggested that I. scapularis SIFamide receptors are class A GPCRs where the peptide amidated carboxy-terminus is oriented within the receptor binding cavity. The receptor was found to be expressed in Ixodes ricinus salivary glands, synganglia, midguts, trachea, and ovaries, but not in Malpighian tubules. Investigation of the temporal expression patterns suggests that the receptor transcript is highly expressed in unfed I. ricinus female salivary glands and then decreases during feeding. In synganglia, a significant transcript increase was detected in replete ticks. In salivary gland acini, an antibody targeting the SIFa_R2 recognized basal epithelial cells, myoepithelial cells, and basal granular cells in close proximity to the SIFamide-releasing axon terminals. Immunoreactivity was also detected in specific neurons distributed throughout various I. ricinus synganglion locations. The current findings, alongside previous reports from our group, indicate that the neuropeptide SIFamide acts via two different receptors that regulate distinct or common cell types in the basal region of type II and III acini in I. ricinus salivary glands. Our study investigates the peptidergic regulation of the I. ricinus salivary gland in detail, emphasizing the complexity of this system. [Display omitted] • Ixodes scapularis SIFamide receptor 2 (SIFa_R2) displays high affinity for SIFamide as well as to its insect paralogs. • I. scapularis SIFa_R1 displays exclusive affinity for SIFamide and not to its insect paralogs. • SIFa_R2 is expressed in I. ricinus salivary glands, synganglion, midguts, trachea, and ovaries. • SIFa_R2 is localized in distinct basal cell types in both type II and III salivary gland acini. [ABSTRACT FROM AUTHOR]

Published

2023