Mayfly and fish species identification and sex determination in bleak (Alburnus alburnus) by MALDI-TOF mass spectrometry.

Besides food quality control of fish or cephalopods, the novel mass spectrometry (MS) approaches could be effective and beneficial methods for the investigation of biodiversity in ecological research. Our aims were to verify the applicability of MALDI-TOF MS in the rapid identification of closely related species, and to further develop it for sex determination in phenotypically similar fish focusing on the low mass range. For MALDI-TOF MS spectra analysis, ClinProTools software was applied, but our observed classification was also confirmed by Self Organizing Map. For verifying the wide applicability of the method, brains from invertebrate and vertebrate species were used in order to detect the species related markers from two mayflies and eight fish as well as sex-related markers within bleak. Seven Ephemera larvae and sixty-one fish species related markers were observed and nineteen sex-related markers were identified in bleak. Similar patterns were observed between the individuals within one species. In contrast, there were markedly diverse patterns between the different species and sexes visualized by SOMs. Two different Ephemera species and male or female fish were identified with 100% accuracy. The various fish species were classified into 8 species with a high level of accuracy (96.2%). Based on MS data, dendrogram was generated from different fish species by using ClinProTools software. This MS-based dendrogram shows relatively high correspondence with the phylogenetic relationships of both the studied species and orders. In summary, MALDI-TOF MS provides a cheap, reliable, sensitive and fast identification tool for researchers in the case of closely related species using mass spectra acquired in a low mass range to define specific molecular profiles. Moreover, we presented evidence for the first time for determination of sex within one fish species by using this method. We conclude that it is a powerful tool that can revolutionize ecological and environmental research.

HPLC-MS/MS analysis of steroid hormones in environmental water samples.

Today, freshwaters, such as lakes and rivers, are subject to controlled pollution. Steroid hormones are chemically very stable highly lipophilic molecules. Their biological properties have a strong impact on the endocrine regulation of species. Steroids have estrogenic, androgenic, thyroidogenic or progestogenic effects and based on them, they could disturb the physiological mechanisms of freshwater species. We focused on progestins as they are the main active ingredients of contraceptive pharmaceuticals. Progestins have been shown to impair reproduction in fish, amphibians, and mollusks at low ng/L concentrations. Certain progestins, such as levonorgestrel (LNG) have androgenic properties also. We selected the most used active substances drospirenone (DRO), LNG, and progesterone (PRG) and then developed and optimized a liquid chromatographic-mass spectrometric method with solid-phase extraction to measure them. Using our sensitive method (LOQ 0.03-0.11 ng/L) we could measure steroids even between 0.1 and 1 ng/L. Analyzing freshwater samples from the Lake Balaton catchment area, we found influents where the concentration of these hormones was 0.26-4.30 (DRO), 0.85-3.40 (LNG), and 0.23-13.67 (PRG) ng/L. Out of 53 collecting places, 21 contained measurable progestin levels, which clearly demonstrates the applicability of our method, legitimates toxicology experiments with effected species, and indicates monitoring efforts.

Down regulation of sodium channels in the central nervous system of hibernating snails.

Hibernation, as behavior, is an evolutionary mode of adaptation of animal species to unfavorable environmental conditions. It is generally characterized by suppressed metabolism, which also includes down regulation of the energy consuming ion-channel functioning. Experimental data regarding decreased ion-channel function are scarce. Therefore, our goal was to study the possible down regulation of voltage-gated sodium channel (NaV) subtypes in the neurons of hibernating snails. Our immunohistochemical experiments revealed that the expression of NaV1.8-like channels in the central nervous system was substantially down regulated in hibernating animals. In contrast to NaV1.8-like, the NaV1.9-like channels were present in neurons independently from hibernating and non-hibernating states. Our western blot data supported the immunohistochemical results according to which the band of the NaV1.8-like channel protein was less intensively labeled in the homogenate of the hibernating snails. The NaV1.9-like immunoreactivity was equally present both in hibernating and active snails. Micro-electrophysiological experiments show that in hibernating snails both NaV1.8- and NaV1.9-like currents are substantially decreased compared to that of the active snails. The contradictory electrophysiological and immunohistochemical or western blot data suggest that the molecular mechanisms of the "channel arrest" could be different in diverse NaV channel subtypes. Climate changes will affect temperature extremes and a question is how different species beyond their physiological tolerance will or able to adapt to changing environment. Hibernation is an important mode of adaptation to extreme climatic variations, and pursuant to this the present results may contribute to the study of the behavioral ecology.

Comparative protein composition of the brains of PACAP-deficient mice using mass spectrometry-based proteomic analysis.

Pituitary adenylate cyclase-activating polypeptide (PACAP) is a widespread neuropeptide acting as a neurotransmitter, neuromodulator, or neurotrophic factor. The diverse biological actions provide the background for the variety of deficits observed in mice lacking endogenous PACAP. PACAP-deficient mice display several abnormalities, such as sudden infant death syndrome (SIDS)-like phenotype, decreased cell protection, and increased risk of Parkinson's disease. However, the molecular and proteomic background is still unclear. Therefore, our aim was to investigate the differences in peptide and protein composition in the brains of PACAP-deficient and wild-type mice using sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and mass spectrometric (MS)-based proteomic analysis. Brains from PACAP-deficient mice were removed, and different brain areas (cortex, hippocampus, diencephalon, mesencephalon, brainstem, and cerebellum) were separated. Brain pieces were weighed, homogenized, and further processed for electrophoretic analysis. Our results revealed several differences in diencephalon and mesencephalon. The protein bands of interest were cut from the gel, samples were digested with trypsin, and the tryptic peptides were measured by matrix-assisted laser desorption ionization time of flight (MALDI TOF) MS. Results were analyzed by MASCOT Search Engine. Among the altered proteins, several are involved in metabolic processes, energy homeostasis, and structural integrity. ATP-synthase and tubulin beta-2A were expressed more strongly in PACAP-knockout mice. In contrast, the expression of more peptides/proteins markedly decreased in knockout mice, like pyruvate kinase, fructose biphosphate aldolase-A, glutathione S-transferase, peptidyl propyl cis-trans isomerase-A, gamma enolase, and aspartate amino transferase. The altered expression of these enzymes might partially account for the decreased antioxidant and detoxifying capacity of PACAP-deficient mice accompanying the increased vulnerability of these animals. Our results provide novel insight into the altered biochemical processes in mice lacking endogenous PACAP.

Voltage-gated membrane currents in neurons involved in odor information processing in snail procerebrum.

The procerebrum (PC) of the snail brain is a critical region for odor discrimination and odor learning. The morphological organization and physiological function of the PC has been intensively investigated in several gastropod species; however, the presence and distribution of ion channels in bursting and non-bursting cells has not yet been described. Therefore, the aim of our study was to identify the different ion channels present in PC neurons. Based on whole cell patch-clamp and immunohistochemical experiments, we show that Na(+)-, Ca(2+)-, and K(+)-dependent voltage-gated channels are differentially localized and expressed in the cells of the PC. Different Na-channel subtypes are present in large (10-15 µm) and small (5-8 µm) diameter neurons, which are thought to correspond to the bursting and non-bursting cells, respectively. Here, we show that the bursting neurons possess fast sodium current (I NaT) and NaV1.9-like channels and the non-bursting neurons possess slow sodium current (I NaT) and NaV1.8-like channels in addition to the L-type Ca(-), KV4.3 (A-type K-channel) and KV2.1 channels. We suggest that the bursting and/or non-bursting character of the PC neurons is at least partly determined by the battery of ion-channels present and their cellular and subcellular compartmentalization.

Multifunctional role of PACAP-like peptides in molluscs.

The purpose of this review is to highlight the role of pituitary adenylate cyclase-activating polypeptide (PACAP) in a range of physiological and behavioral processes of gastropod molluscs, Helix and Lymnaea. Since its discovery in 1989 PACAP has become increasingly recognized for its important and diversified roles in the central and peripheral nervous system and in several peripheral organs of a variety of vertebrate and invertebrate species. Twenty-two years after its discovery, PACAP is now one of the most extensively studied of the neuropeptides. This review surveys the importance of PACAP and PACAP-like peptides in invertebrates, focusing mainly on the gastropod molluscs. The relevance of studies on lower vertebrates and invertebrates, which do not have a pituitary gland, is to contribute to the unraveling of fundamental effects of PACAP or PACAP-like peptides and to provide a comparative view.

High resolution spatial distribution of neuropeptides by MALDI imaging mass spectrometry in the terrestrial snail, Helix pomatia.

Imaging mass spectrometry (IMS) is a powerful technique that combines the chemical and spatial analysis of surface materials. It allows spatial localization of peptides, proteins or lipids that are recorded in parallel without the need of a label. It is currently one of the most rapidly developing techniques in the proteomics toolbox. In the present study, accurate mass matrix-assisted laser desorption/ionization imaging mass spectrometry (MALD IMS) was used for direct molecular mapping of nervous tissue at micrometer spatial resolution. Cryosections of the whole brain of the terrestrial snail, Helix pomatia, were placed on indium-tin-oxide (ITO)-coated conductive glass slides and covered with a thin layer of α-cyano-4-hydroxycinnamic acid (CHCA) matrix by electro spray deposition. High-resolution molecular ion maps of well-known neuropeptides, such as FMRFamide were constructed. FMRFamide is known to exert powerful modulatory effect on synaptic transmission in molluscs. FMRFamide was predominantly localized in the cluster of neurons in the pro-, meso- and postcerebral regions of cerebral ganglia, pedal ganglia and right parietal ganglia of the central nervous system. Our present study, using MALDI IMS confirmed the distribution of FMRFamide containing cells in the Helix central nervous system previously detected by antibody dependent immunohistochemistry.

Cellular localization and kinetic properties of Na(V)1.9-, Na(V)1.8-, and Na(V)1.7-like channel subtypes in Helix pomatia.

This article concerns the kinetics, selectivity, and distribution of the Na(V)1.9, Na(V)1.8, and Na(V)1.7 channel subtypes in the CNS of the snail, Helix pomatia. Within the snail brain, Na(V)1.9- and Na(V)1.8-like channel subtypes are widely expressed, with particularly high levels in the pedal, cerebral, and buccal ganglia. The suboesophageal ganglion contains equal amounts of neurons labeled with Na(V)1.9, 1.8, and 1.7 antibodies. Our data show that different types of ion channels are localized to discrete neurons and regions of the neuronal membrane affecting by this way the physiology of synaptic transmission or nerve conduction. Based on the voltage dependence and kinetics, the non- or slowly inactivating currents were observed in identified and nonidentified neurons of the snail CNS attributed to separate Na-channel subtypes. These observations provide the first evidence for the presence of the composite Na-current in snail neurons. The significance of Na(V)1.9 channels in gastropod neurons is assigned to regulating the subthreshold membrane depolarization. First time, we have demonstrated that in addition to the Na(V)1.2-like channels most of the neurons contain Na(V)1.8- or 1.7-like channels carrying the composite inward sodium current. In this way, neurons containing different sets of channels differently are regulated, which allows further dynamic modulation of neuronal activity. The neuronal soma membrane revealed low ion selectivity of the Na-channels with slow kinetics, which is a general property of gastropod molluscs. In addition, the relative similarity of the biophysical properties of voltage-gated currents between vertebrates and invertebrates may reflect a structural similarity existing between Na-channel subtypes pointing to a common evolutionary origin.

Mass spectrometric analysis of activity-dependent changes of neuropeptide profile in the snail, Helix pomatia.

Terrestrial snails are able to transform themselves into inactivity ceasing their behavioral activity under unfavorable environmental conditions. In the present study, we report on the activity-dependent changes of the peptide and/or polypeptide profile in the brain and hemolymph of the snail, Helix pomatia, using MALDI TOF and quadrupole mass spectrometry. The present data indicate that the snails respond to low temperature by increasing or decreasing the output of selected peptides. Average mass spectra of the brain and hemolymph revealed numerous peaks predominantly present during the active state (19 and 10 peptides/polypeptides, respectively), while others were observed only during hibernation (11 and 13). However, there were peptides and/or polypeptides or their fragments present irrespective of the activity states (49 and 18). The intensity of fourteen peaks that correspond to previously identified neuropeptides varied in the brain of active snails compared to those of hibernating animals. Among those the intensity of eight peptides increased significantly in active animals while in hibernated animals the intensity of another six peptides increased significantly. A new peptide or peptide fragment at m/z 1110.7 was identified in a brain of the snail with the following suggested amino acid sequence: GSGASGSMPATTS. This peptide was found to be more abundant in active animals because the intensity of the peptide was significantly higher compared to hibernating animals. In summary, our results revealed substantial differences in the peptide/polypeptide profile of the brain and hemolymph of active and hibernating snails suggesting a possible contribution of peptides in the process of hibernation.

The presence and distribution of pituitary adenylate cyclase activating polypeptide and its receptor in the snail Helix pomatia.

The aim of this study was to show the presence, distribution and function of the pituitary adenylate cyclase activating polypeptide (PACAP) and its receptors in the CNS and peripheral nervous system of the mollusk, Helix pomatia. PACAP-like and pituitary adenylate cyclase activating polypeptide receptor (PAC1-R)-like immunoreactivity was abundant both in the CNS and the peripheral nervous system of the snail. In addition several non-neuronal cells also revealed PACAP-like immunoreactivity. In inactive animals labeled cell bodies were mainly found and in the neuropile of active animals dense immunostained fiber system was additionally detected suggesting that expression of PACAP-like peptide was affected by the behavioral state of the animal. RIA measurements revealed the existence of both forms of PACAP in the CNS where the 27 amino acid form was found to be dominant. The concentration of PACAP27 was significantly higher in samples from active animals supporting the data obtained by immunohistochemistry. In Western blot experiments PACAP27 and PACAP38 antibodies specifically labeled protein band at 4.5 kDa both in rat and snail brain homogenates, and additionally an approximately 14 kDa band in snail. The 4.5 kDa protein corresponds to PACAP38 and the 14 kDa protein corresponds to the preproPACAP or to a PACAP-like peptide having larger molecular weight than mammalian PACAP38. In matrix-assisted laser desorption ionization time of flight (MALDI TOF) measurements fragments of PACAP38 were identified in brain samples suggesting the presence of a large molecular weight peptide in the snail. Applying antibodies developed against the PACAP receptor PAC1-R, immunopositive stained neurons and a dense network of fibers were identified in each of the ganglia. In electrophysiological experiments, extracellular application of PACAP27 and PACAP38 transiently depolarized or increased postsynaptic activity of neurons expressing PAC1-R. In several neurons PACAP elicited a long lasting hyperpolarization which was eliminated after 1.5 h continuous washing. Taken together, these results indicate that PACAP may have significant role in a wide range of basic physiological functions in snail.