Nina Trokovic

FGFR1 is independently required in both developing mid- and hindbrain for sustained response to isthmic signals.

Fibroblast growth factors (FGFs) are signaling molecules of the isthmic organizer, which regulates development of the midbrain and cerebellum. Tissue‐specific inactivation of one of the FGF receptor (FGFR) genes, Fgfr1, in the midbrain and rhombomere 1 of the hindbrain of mouse embryos results in deletion of the inferior colliculi in the posterior midbrain and vermis of the cerebellum. Analyses of both midbrain–hindbrain and midbrain‐specific Fgfr1 mutants suggest that after establishment of the isthmic organizer, FGFR1 is needed for continued response to the isthmic signals, and that it has direct functions on both sides of the organizer. In addition, FGFR1 appears to modify cell adhesion properties critical for maintaining a coherent organizing center. This may be achieved by regulating expression of specific cell‐adhesion molecules at the midbrain–hindbrain border.

Sex steroids in Sjögren's syndrome.

The purpose of the review is to consider pathomechanisms of Sjögrens syndrome (SS), which could explain the female dominance (9:1), the most common age of onset (40-50 years) and targeting of the exocrine glands. Estrogens seem to specifically protect secretory glandular acinar cells against apoptosis whereas lack of estrogens during menopause and climacterium specifically leads to increased apoptosis of the exocrine secretory cells. Male gonads produce testosterone and convert it in exocrine glands to dihydrotesterosterone (DHT), which is anti-apoptotic and protects against acinar cell apoptosis. Estrogen-deficient women need to produce dehydroepiandrosterone (DHEA) in the adrenal glands and convert it to DHT in exocrine glands in a complex and branching reaction network in which individual enzymatic reactions are catalyzed in forward and backward directions by a myriad of different isoforms of steroidogenic enzymes. Tailoring DHT in peripheral tissues is much more complex and vulnerable in women than in men. In SS the intracrine steroidogenic enzyme machinery is deranged. These endo-/intracrine changes impair acinar remodeling due to impaired integrin α1β1 and integrin α2β1 expression so that the intercalated duct progenitor cells are unable to migrate to the acinar space, to differentiate to secretory acinar cells upon contact with laminin-111 and laminin-211 specifically found in the acinar basement membrane. The disarranged endo-/intracrine estrogen/androgen balance induces acinar cells to release microparticles and apoptotic bodies and to undergo apoptotis and/or anoikis. Membrane particles contain potential autoantigens recognized by T- (TCRs) and B-cell receptors (BCRs) and danger-associated molecular patterns (DAMPs) recognized by Toll-like receptors (TLRs). In membrane particles (or carrier-complexes) antigen/adjuvant complexes could stimulate professional antigen capturing, processing and presenting cells, which can initiate auto-inflammatory and autoimmune cascades, break the self-tolerance and finally lead to SS.

RANKL in the osteolysis of AES total ankle replacement implants

Peri-implant tissue reactions in failed total ankle replacement (TAR) are characterized by early developing peri-implant osteolysis. The hypothesis of the study was that this reaction is mediated by receptor activator of nuclear factor kappa B ligand (RANKL). Samples of peri-prosthetic tissues from failed TAR implants were stained for macrophages, RANKL, its receptor RANK and osteoprotegerin (OPG), and compared to control samples. The failed TAR implants were surrounded by implant capsule, synovial lining-like interface membrane or necrotic tissues. Infiltrating scavenger receptor I positive CD163(+) macrophages were frequent, in particular around necrotic soft tissues or bone sequestrate, and possibly in part formed due to ischemia and mechanical factors. In contrast, implant-derived wear debris was scanty. Still many RANK(+) macrophages were often seen in close contact with RANKL(+) mesenchymal cells, whereas OPG was mostly located at a distance in vascular endothelial cells. Foreign body giant cells were frequent. RANKL seems to stimulate locally accumulated CD163(+) RANK-expressing cells to fusion, which leads to the local formation of multinuclear foreign body giant cells (and probably of osteoclasts). Therefore, peri-implant osteolysis in early TAR implant failure seems to be caused by the RANKL-driven chronic foreign body inflammation directed against, not implant-derived particles, but against necrotic autologous tissues.

Intraspecific divergence in the lateral line system in the nine-spined stickleback (Pungitius pungitius)

The mechanosensory lateral line system of fishes is an important organ system conveying information crucial to individual fitness. Yet, our knowledge of lateral line diversity is almost exclusively based on interspecific studies, whereas intraspecific variability and possible population divergence have remained largely unexplored. We investigated lateral line system variability in four marine and five pond populations of nine‐spined stickleback (Pungitius pungitius). We found significant differences in neuromast number between pond and marine fish. In particular, three of seventeen lateral line regions (viz. caudal peduncle superficial neuromasts; canal neuromasts from the anterior trunk and caudal peduncle) showed strong divergence between habitats. Similar results were obtained with laboratory‐reared individuals from a subset of populations, suggesting that the patterns found in nature likely have a genetic basis. Interestingly, we also found habitat‐dependent population divergence in neuromast variability, with pond populations showing greater heterogeneity than marine populations, although only in wild‐caught fish. A comparison of neutral genetic (FST) and phenotypic (PST) differentiation suggested that natural selection is likely associated with habitat‐dependent divergence in neuromast counts. Hence, the results align with the conclusion that the mechanosensory lateral line system divergence among marine and pond nine‐spined sticklebacks is adaptive.

Use of MGLUR2 and MGLUR3 knockout mice to explore in vivo receptor specificity of the MGLUR2/3 selective antagonist LY341495

LY341495 is a metabotropic glutamate receptor (mGluR) antagonist showing selectivity to mGluR2/3 but having measurable antagonist efficacy across all mGluR subtypes at 10-1000 fold higher concentrations. In vivo in rodents it increases locomotor activity and wakefulness, enhances cognition and modulates emotions. It also induces widespread neuronal activation measured as c-Fos expression. To further investigate the receptor subtypes through which LY341495 might act in vivo we analyzed how its effects are altered in mGluR2-knockout (KO) and mGluR3-KO brains. In most regions, LY341495 (3 mg/kg, i.p., 2.5 h) -induced c-Fos expression was not altered in either KO brain. However, in mGluR3-KO mice, LY341495 was almost inactive in the central extended amygdala [central nucleus of the amygdala, lateral (CeL) and bed nucleus of the stria terminalis, laterodorsal (BSTLD)], suggesting that acute blockade of mGluR3 is activating these neurons in wildtype brain. In the ventrolateral nucleus of the thalamus (VL), LY341495 produced a significantly enhanced response in mGluR3-KO mice and attenuated response in mGluR2-KO mice. We also analyzed locomotion in familiar environment and found that locomotor activity was dose-dependently increased by LY341495 (1-30 mg/kg, i.p.) regardless of the genotype. In unfamiliar environment, both KO strains showed enhanced sensitivity to LY341495 in reducing locomotor habituation. Together our results indicate that certain effects of LY341495 may not be mediated by a blockade of either mGluR2 or mGluR3, but may involve other mGluR subtypes. Alternatively, functions of mGluR2 and mGluR3 may be redundant, resulting similar effects irrespective the receptor subtype being antagonized in vivo by LY341495.

Predation- and competition-mediated brain plasticity in Rana temporaria tadpoles

An increasing number of studies have demonstrated phenotypic plasticity in brain size and architecture in response to environmental variation. However, our knowledge on how brain architecture is affected by commonplace ecological interactions is rudimentary. For example, while intraspecific competition and risk of predation are known to induce adaptive plastic modifications in morphology and behaviour in a wide variety of organisms, their effects on brain development have not been studied. We studied experimentally the influence of density and predation risk on brain development in common frog (Rana temporaria) tadpoles. Tadpoles grown at low density and under predation risk developed smaller brains than tadpoles at the other treatment combinations. Further, at high densities, tadpoles developed larger optic tecta and smaller medulla oblongata than those grown at low densities. These results demonstrate that ecological interactions – like intraspecific competition and predation risk – can have strong effects on brain development in lower vertebrates.

High levels of fluctuating asymmetry in isolated stickleback populations

BackgroundFluctuating asymmetry (FA), defined as small random deviations from the ideal bilateral symmetry, has been hypothesized to increase in response to both genetic and environmental stress experienced by a population. We compared levels of FA in 12 bilateral meristic traits (viz. lateral-line system neuromasts and lateral plates), and heterozygosity in 23 microsatellite loci, among four marine (high piscine predation risk) and four pond (zero piscine predation risk) populations of nine-spined sticklebacks (Pungitius pungitius).ResultsPond sticklebacks had on average three times higher levels of FA than marine fish and this difference was highly significant. Heterozygosity in microsatellite markers was on average two times lower in pond (HE ≈ 0.3) than in marine (HE ≈ 0.6) populations, and levels of FA and heterozygosity were negatively correlated across populations. However, after controlling for habitat effect on heterozygosity, levels of FA and heterozygosity were uncorrelated.ConclusionsThe fact that levels of FA in traits likely to be important in the context of predator evasion were elevated in ponds compared to marine populations suggests that relaxed selection for homeostasis in ponds lacking predatory fish may be responsible for the observed habitat difference in levels of FA. This inference also aligns with the observation that the levels of genetic variability across the populations did not explain population differences in levels of FA after correcting for habitat effect. Hence, while differences in strength of selection, rather than in the degree of genetic stress could be argued to explain habitat differences in levels of FA, the hypothesis that increased FA in ponds is caused by genetic stress cannot be rejected.

Recurrent aphthous ulcers—a Toll‐like receptor–mediated disease?

BACKGROUND Recurrent aphthous ulcer (RAU) is characterized by acute and painful inflammatory ulcerations, which heal spontaneously but tend to recur. Many pathogens have been proposed as causative agents, but none has been consistently proven. According to our hypothesis, RAU is an autoinflammatory disorder triggered by pathogen-associated molecular patterns (PAMPs) shared by different pathogenic and commensal microbes. METHODS PAMP-reactive Toll-like receptors (TLRs) were mapped in oral epithelium in healthy controls compared to RAU. RESULTS In controls, the superficial epithelium formed a TLR(-), a PAMP non-reactive physical barrier zone, but all TLRs were found deeper in the epithelium, usually restricted to suprabasal and basal cell layers. In RAU, the epithelial TLR polarity was lost: TLRs 1, 2, 5, 7, and 8 were found throughout the epithelium, but also TLRs 4, 6, and 10 extended higher up than normally, whereas TLR-3 was almost lost in RAU. In RAU lesions, connective tissue stroma was heavily infiltrated by TLR(+) inflammatory cells. CONCLUSIONS Normal TLR architecture prevents inflammatory responses against normal microbes but still contains a deep TLR(+) , PAMP-reactive dormant defense zone. In RAU, the TLR(+), PAMP-reactive zone extends to surface or subsurface exposed to microbial PAMPs. TLR reactivity is further enhanced by recruitment of inflammatory leukocytes forming a new deep line of defense. The organization of the TLR system in healthy mucosa and its changes in RAU are compatible with active pathogenic involvement of TLRs, which together with the typical clinical picture and course suggest that RAU is a TLR-mediated disease.

Brain plasticity over the metamorphic boundary: Carry-over effect of larval environment on froglet brain development

Brain development shows high plasticity in response to environmental heterogeneity. However, it is unknown how environmental variation during development may affect brain architecture across life history switch points in species with complex life cycles. Previously, we showed that predation and competition affect brain development in common frog (Rana temporaria) tadpoles. Here, we studied whether larval environment had carry‐over effects in brains of metamorphs. Tadpoles grown at high density had large optic tecta at metamorphosis, whereas tadpoles grown under predation risk had small diencephala. We found that larval density had a carry‐over effect on froglet optic tectum size, whereas the effect of larval predation risk had vanished by metamorphosis. We discuss the possibility that the observed changes may be adaptive, reflecting the needs of an organism in given environmental and developmental contexts.

Exosomal secretion of death bullets: a new way of apoptotic escape?

Ovariectomy/estrogen deficiency causes selective apoptosis of the serous epithelial cells of the submandibular glands (SMG) in female mice. Because such apoptosis does not occur in healthy, estrogen-deficient male mice, it was hypothesized that dihydrotestosterone (DHT) protects epithelial SMG cells against apoptosis. The antiapoptotic effect of DHT on human epithelial HSG cells exposed to tumor necrosis factor-α and cycloheximide was studied. Correspondingly, the proapoptotic effect of androgen deficiency was studied in orchiectomized (ORX) androgen-knockout (ARKO) and wild-type (WT) mice. The health state of the SMG cells was studied with Alcian blue-periodic acid Schiff (AB-PAS) and amylase staining and transmission electron microscopy (TEM). The eventual protective antiapoptotic effect of dehydroepiandrosterone (DHEA) treatment was tested in this model. Apoptosis was assessed using immunohistochemisty of cleaved effector caspase-3 and its activator caspase-8 and the TUNEL assay. To test for the bioavailability, intracrine metabolism and sex steroid effects of DHEA, cystein-rich secretory protein-3 (CRISP-3), and leucine-isoleucine-valine transport system 1 (LIV-1) were used as androgen- and estrogen-regulated biomarkers, respectively. DHT protected HSG cells against induced apoptosis. In mice, androgen deficiency resulted in extensive activation of apoptotic caspase-8/3 cascade in serous epithelial cells. However, in salivary glands, active caspases were not translocated to nuclei but secreted to salivary ducts in exosome-like particles, which are associated with weak AB-PAS and amylase staining of the androgen-deprived cells and reduced number of intracellular secretory granules. DHEA treatment suppressed induction of proapoptotic caspases and almost normalized mucins and amylase and ultramophology of the serous epithelial cells in WT ORX but not ARKO ORX mice. According to the CRISP-3 and LIV-1 markers, DHEA probably exerted its effects via intracrine conversion to DHT.