Jürgen Krücken

Cyclooctadepsipeptides: an anthelmintically active class of compounds exhibiting a novel mode of action

There are three major classes of anthelmintics for veterinary use: the benzimidazoles/prebenzimidazoles, the tetrahydropyrimidines/imidazothiazoles, and the macrocyclic lactones. In nematodes, there are five targets for the existing anthelmintics: the nicotinergic acetylcholine receptor which is the target of tetrahydropyrimidines/imidazothiazoles and indirectly that of the acetylcholineesterase inhibitors; the GABA receptor which is the target of piperazine, the glutamate-gated chloride channel as the target of the macrocyclic lactones, and beta-tubulin as the target of prebenzimidazoles/benzimidazoles. All these anthelmintics are now in serious danger because of the worldwide spread of resistant nematodes in sheep, cattle, horses and pigs. The class of cyclooctadepsipeptides has entered the scene of anthelmintic research in the early 1990s. PF1022A, the first anthelmintically active member, is a natural compound from the fungus Mycelia sterilia that belongs to the microflora of the leaves of the Camellia japonica. PF1022A contains 4 N-Methyl-L-leucines, 2 D-lactic acids and 2-D-phenyllactic acids arranged as a cyclic octadepsipeptide with an alternating L-D-L-configuration. Emodepside is a semisynthetic derivative of PF1022A with a morpholine ring at each of the two D-phenyllactic acids in para position. The anthelmintic activity is directed against gastrointestinal nematodes in chicken, mice, rats, meriones, dogs, cats, sheep, cattle and horses. Moreover, emodepside is active against Trichinella spiralis larvae in muscles, microfilariae and preadult filariae and Dictyocaulus viviparus. PF1022A and emodepside are fully effective against benzimidazole-, levamisole or ivermectin-resistant nematodes in sheep and cattle. In Ascaris suum both cyclooctadepsipeptides lead to paralysis indicating a neuropharmacological action of these compounds. Using a PF1022A-ligand immunoscreening of a cDNA library from Haemonchus contortus a cDNA clone of 3569 base pairs could be identified. This clone codes for a novel 110 kDa heptahelical transmembrane receptor, named HC110R. Database- and phylogenetic analysis reveals that this receptor is a homolog to B0457.1 from Caenorhabditis elegans and has significant similarity to latrophilins from human, cattle and rat. HC110R is located in the plasma membrane and in lysosomes and endosomes. Alpha-latrotoxin, the poison of the black widow spider, binds at a 54 kDa aminoterminal fragment of HC110R. After binding a Ca2+-influx into HEK293 cells is induced which can be blocked by EGTA, Cd2+ or nifedipin. PF1022A or emodepside also bind to this 54 kDa aminoterminal region of HC110R and interact with the functional responses of alpha-latrotoxin. In C. elegans antibodies against the C-or N-terminus of HC110R bind to the B0457.1 protein located in the pharynx. Electrophysiological studies reveal that emodepside inhibits pharyngeal pumping of the nematodes in a concentration dependent way with an IC(50) value of about 4 nM. Thus, it is tempting to speculate that emodepside exerts its action on nematodes via a latrophilin-like receptor which might have an important regulatory function on pharyngeal pumping.

Nongenomic testosterone calcium signaling. Genotropic actions in androgen receptor-free macrophages.

Steroid hormones exert genotropic actions through members of the nuclear receptor family. Here, we have demonstrated genotropic actions of testosterone that are independent of intracellular androgen receptors (iAR). Through plasma membrane androgen receptors (mAR), testosterone induces a rapid rise in the intracellular free Ca2+ concentration of iAR-free murine RAW 264.7 macrophages. This nongenomic testosterone signaling, which is independent of both iAR and estrogen receptors, does not in itself activate either the mitogen-activated protein kinase (MAPK) families ERK1/2, p38, and JNK/SAPK, the stably and transiently transfected c-fos promoter, or NO production. In the context of lipopolysaccharide (LPS) signaling, however, testosterone attenuates LPS activation of the c-fos promoter and NO production, which is abolished by the intracellular Ca2+chelator BAPTA. Testosterone also attenuates the LPS activation of p38 but not that of ERK1/2 and JNK/SAPK, and this attenuation is abrogated by BAPTA. Moreover, the p38 inhibitor, SB 203580, largely reduces LPS activation of the c-fos promoter and NO production, and the remaining levels are no longer regulated by testosterone. This study is the first to provide information on genotropic actions of mAR-mediated nongenomic testosterone Ca2+ signaling by cross-talk with the LPS signaling pathway through p38 MAPK with impact on cell function.

Recent advances in candidate-gene and whole-genome approaches to the discovery of anthelmintic resistance markers and the description of drug/receptor interactions

Graphical abstract

Molecular epidemiology of Cryptosporidium in livestock animals and humans in the Ismailia province of Egypt.

The zoonotic potential of Cryptosporidium was studied in one of the most densely populated provinces of Egypt regarding livestock and people. In a representative survey, faecal samples from cattle, buffalo and stool samples from diarrhoeic children (<10 years) were investigated. Parameters assumed to be related to cryptosporidiosis were recorded for animals and children. Animal samples (804) were examined by the Copro-antigen RIDA(®)QUICK test, followed by PCRs targeting the 18S rDNA and gp60 genes for antigen-positive and 10% randomly selected negative samples. All 165 human samples were tested by both methods. The overall estimated prevalence of Cryptosporidium in ruminants was 32.2%, without significant difference between animal species. PCR identified 65.7% Cryptosporidium parvum, 11.8% Cryptosporidium ryanae, 4.1% Cryptosporidium bovis, and combinations of C. parvum plus C. ryanae (11.2%), C. parvum plus C. bovis (5.3%) and of C. parvum plus Cryptosporidium andersoni (1.8%), also without significant differences in species occurrence between cattle and buffalos. The human Cryptosporidium spp. prevalence was 49.1%, of which 60.5% were Cryptosporidium hominis, 38.2% C. parvum and 1.2% C. parvum plus C. bovis. Analysis of gp60 variants allocated C. parvum found in animals to the zoonotic subtype family IIa (18.9%, subtype IIaA15G1R1 only) and to IId (81.1%, mostly IIdA20G1). In humans 50% were classified as subtype family IIa (IIaA15G1R1 and IIaA15G2R1) and 50% were IIdA20G1. C. andersoni occurred only in cattle older than 1 year. In contrast, mono-infections with one of the three single Cryptosporidium species and the three combinations with C. parvum were more prevalent in cattle and buffaloes younger than 1 year, particularly in those younger than 3 months, and were predominantly subtype family IId. In human samples no Cryptosporidium were identified in children younger than 7 months. Neither place of residence nor the source of drinking-water had measurable effects on prevalence. Remarkably, however, all children with C. parvum subtype family IIa and 86% with subtype family IId had contact to animals. High prevalence and identical genotypes of C. parvum in animals and humans indicate zoonotic transmission due to contact with animals, involving IIdA20G1 as the most frequent subtype.

Latrophilin-like receptor from the parasitic nematode Haemonchus contortus as target for the anthelmintic depsipeptide PF1022A.

PF1022A belongs to a new class of cyclodepsipeptides with broad anthelmintic activity. Here, we describe a novel target for PF1022A. Using PF1022A ligand immunoscreening of a cDNA library constructed from the parasitic nematode Haemonchus contortus, we identified a 3539 bp cDNA encoding a novel orphan heptahelical transmembrane 110 kDa‐receptor, termed HC110‐ R, similar to the mammalian G‐protein coupled receptor latrophilin. HC110‐R is localized at plasma membranes and in intracellular vesicles of HC110‐R‐transfected HEK‐293 cells. The ligand of latrophilin, a‐latrotoxin (LTX), binds to the extracellular N‐terminal region of HC110‐ R and induces influx of external Ca2+ through Cd2+‐ and nifedipine‐blockable Ca2+ channels. PF1022A also binds to the N‐terminus of HC110‐R and acts as an antagonist to LTX signaling in HC110‐R transfected HEK‐293 cells.

Rapid effects of androgens in macrophages.

We investigated the existence of membrane receptors for testosterone (mAR) in mouse macrophages of the cell lines IC-21 and RAW 264.7 as well as their roles in nongenomic pathways, gene expression and cell functioning. Both cell lines lack intracellular androgen receptors (iARs) and respond to testosterone with rapid rises in [Ca2+]i. These rises in [Ca2+]i can neither be inhibited by iAR- nor by iER blockers, but are rather mediated through mAR. Pharmacological approaches suggest that the mAR belongs to the class of membrane receptors which are coupled to phospholipase C via pertussis toxin (PTX) sensitive G-proteins. The mAR can be localized as specific surface binding sites for testosterone-BSA-FITC by confocal laser scanning microscopy (CLSM)and flow cytometry, and are characterized by their agonist-sequestrability. In order to examine a possible role of the testosterone-induced rise in [Ca2+]i on gene expression, a c-fos promoter reporter gene construct was transfected into RAW 264.7 macrophages. The increase in [Ca2+]i induced by testosterone cannot significantly activate the c-fos promoter directly. Also, no significant activation of ERK1/2, JNK/SAPK and p38 can be observed following testosterone-stimulation alone. However, testosterone-induced rises in [Ca2+]i do have specific effects on gene expression in context with lipopolysaccharide (LPS)-induced genotropic signaling: testosterone specifically down-regulates LPS-induced activation of c-fos promoter, p38 MAPK and NO production. In fetal calf serum (FCS)-induced genotropic signaling, the situation is reversed, i.e. testosterone augments the activation of c-fos promoter and ERK1/2. Our studies demonstrate a cross-talk between the testosterone-induced nongenomic Ca2+ signaling and the genotropic signaling induced by LPS and FCS in macrophages.

Testosterone Suppresses Protective Responses of the Liver to Blood-Stage Malaria

ABSTRACT Testosterone induces a lethal outcome in otherwise self-healing blood-stage malaria caused by Plasmodium chabaudi. Here, we examine possible testosterone effects on the antimalaria effectors spleen and liver in female C57BL/6 mice. Self-healing malaria activates gating mechanisms in the spleen and liver that lead to a dramatic reduction in trapping activity, as measured by quantifying the uptake of 3-μm-diameter fluorescent polystyrol particles. However, testosterone delays malaria-induced closing of the liver, but not the spleen. Coincidently, testosterone causes an ∼3- to 28-fold depression of the mRNA levels of nine malaria-responsive genes, out of 299 genes tested, only in the liver and not in the spleen, as shown by cDNA arrays and Northern blotting. Among these are the genes encoding plasminogen activator inhibitor (PAI1) and hydroxysteroid sulfotransferase (STA2). STA2, which detoxifies bile acids, is suppressed 10-fold by malaria and an additional 28-fold by testosterone, suggesting a severe perturbation of bile acid metabolism. PAI1 is protective against malaria, since disruption of the PAI1 gene results in partial loss of the ability to control the course of P. chabaudi infections. Collectively, our data indicate that the liver rather than the spleen is a major target organ for testosterone-mediated suppression of resistance against blood-stage malaria.

Human ortholog to mouse gene imap38 encoding an ER-localizable G-protein belongs to a gene family clustered on chromosome 7q32-36

Inducibility of the mouse gene imap38 in the spleen has been recently described to correlate with resistance to Plasmodium chabaudi malaria. Here, we characterize the human ortholog gene himap1. The HIMAP1 34 kDa protein is localizable at the endoplasmic reticulum in transfected cells. It contains a GTP-binding domain, but it does not bind GTP, in contrast to mouse IMAP38. The himap1 gene belongs to a gene family clustered on chromosome 7q32-36 within a region highly syntenic to the mouse imap38 locus on chromosome 6B. The himap genes 1, 2, 3, and 4 display a conserved intron/exon structure. The mRNA of the himap1 gene is predominantly expressed in the spleen, in lymph nodes to a lesser extent, and only at very low levels in diverse cancer cell lines. In accordance, imap-like genes in mice and plants are associated with proliferative and apoptotic events suggesting a role in the control of cell death/survival.

Massive Destruction of Malaria-Parasitized Red Blood Cells despite Spleen Closure

ABSTRACT It is currently accepted that malaria-parasitized red blood cells (pRBC) are eliminated, like senescent erythrocytes, phagocytically by macrophages in the red pulp of the spleen. Here, however, we show that self-healing Plasmodium chabaudi malaria activates spleen closure in C57BL/6 mice. Confocal laser scanning microscopy revealed that spleen closing was manifested by elimination of entry into the red pulp of 3-μm polystyrol particles, pRBC, and nonparasitized red blood cells but not of bovine serum albumin. This spleen closure did not reflect a reduction in the number of phagocytic cells, as shown by flow cytometry, whereas marginal zone macrophages (MZM) were lost and red pulp macrophages entered the white pulp. Splenic trapping of pBRC was strongly reduced in the absence of MZM and marginal metallophilic macrophages (MMM), as it is in noninfected mice with a disrupted lymphotoxin β receptor (LTβR−/−), and it was still significantly reduced when the number of MZM and MMM was diminished, as in tumor necrosis factor alpha-deficient (TNF-α−/−) mice. Moreover, mice deficient in TNF-α, tumor necrosis factor receptor I (TNFRI−/−), and LTβR exhibited progressive impairment in malaria-induced spleen closing. Treatment of C57BL/6 mice with TNF-α induced loss of MZM and spleen closing by about 20%. Our data indicate that TNF/TNFRI signaling is involved in regulating malaria-induced spleen closure, which is maximal during crisis, when parasitemia declines more than 100-fold. Consequently, the vast majority of pRBC cannot be destroyed by the spleen during crisis, suggesting that the known sophisticated sequestration system of Plasmodium parasites did not evolve to avoid splenic clearance.

Discrimination of Gastrointestinal Nematode Eggs from Crude Fecal Egg Preparations by Inhibitor-Resistant Conventional and Real-Time PCR

Diagnosis of gastrointestinal nematodes relies predominantly on coproscopic methods such as flotation, Kato-Katz, McMaster or FLOTAC. Although FLOTAC allows accurate quantification, many nematode eggs can only be differentiated to genus or family level. Several molecular diagnostic tools discriminating closely related species suffer from high costs for DNA isolation from feces and limited sensitivity since most kits use only small amounts of feces (<1 g). A direct PCR from crude egg preparations was designed for full compatibility with FLOTAC to accurately quantify eggs per gram feces (epg) and determine species composition. Eggs were recovered from the flotation solution and concentrated by sieving. Lysis was achieved by repeated boiling and freezing cycles – only Trichuris eggs required additional mechanic disruption. Egg lysates were directly used as template for PCR with Phusion DNA polymerase which is particularly resistant to PCR inhibitors. Qualitative results were obtained with feces of goats, cattle, horses, swine, cats, dogs and mice. The finally established protocol was also compatible with quantitative real-time PCR in the presence of EvaGreen and no PCR inhibition was detectable when extracts were diluted at least fourfold. Sensitivity was comparable to DNA isolation protocols and spiked samples with five epg were reliably detected. For Toxocara cati a detection limit below one epg was demonstrated. It was possible to distinguish T. cati and Toxocara canis using high resolution melt (HRM) analysis, a rapid tool for species identification. In human samples, restriction fragment length polymorphism (RFLP) and HRM analysis were used to discriminate Necator americanus and Ancylostoma duodenale. The method is able to significantly improve molecular diagnosis of gastrointestinal nematodes by increasing speed and sensitivity while decreasing overall costs. For identification of species or resistance alleles, analysis of PCR products with many different post PCR methods can be used such as RFLP, reverse-line-blot, Sanger sequencing and HRM.