LIM-kinase 1 effects on memory abilities and male courtship song in Drosophila depend on the neuronal type.

The signal pathway of actin remodeling, including LIM-kinase 1 (LIMK1) and its substrate cofilin, regulates multiple processes in neurons of vertebrates and invertebrates. Drosophila melanogaster is widely used as a model object for studying mechanisms of memory formation, storage, retrieval and forgetting. Previously, active forgetting in Drosophila was investigated in the standard Pavlovian olfactory conditioning paradigm. The role of specific dopaminergic neurons (DAN) and components of the actin remodeling pathway in different forms of forgetting was shown. In our research, we investigated the role of LIMK1 in Drosophila memory and forgetting in the conditioned courtship suppression paradigm (CCSP). In the Drosophila brain, LIMK1 and p-cofilin levels appeared to be low in specific neuropil structures, including the mushroom body (MB) lobes and the central complex. At the same time, LIMK1 was observed in cell bodies, such as DAN clusters regulating memory formation in CCSP. We applied GAL4 × UAS binary system to induce limk1 RNA interference in different types of neurons. The hybrid strain with limk1 interference in MB lobes and glia showed an increase in 3-h short-term memory (STM), without significant effects on long-term memory. limk1 interference in cholinergic neurons (CHN) impaired STM, while its interference in DAN and serotoninergic neurons (SRN) also dramatically impaired the flies' learning ability. By contrast, limk1 interference in fruitless neurons (FRN) resulted in increased 15-60 min STM, indicating a possible LIMK1 role in active forgetting. Males with limk1 interference in CHN and FRN also showed the opposite trends of courtship song parameters changes. Thus, LIMK1 effects on the Drosophila male memory and courtship song appeared to depend on the neuronal type or brain structure.

Parent-of-origin effects on nuclear chromatin organization and behavior in a Drosophila model for Williams-Beuren Syndrome.

Prognosis of neuropsychiatric disorders in progeny requires consideration of individual (1) parent-of-origin effects (POEs) relying on (2) the nerve cell nuclear 3D chromatin architecture and (3) impact of parent-specific miRNAs. Additionally, the shaping of cognitive phenotypes in parents depends on both learning acquisition and forgetting, or memory erasure. These processes are independent and controlled by different signal cascades: the first is cAMPdependent, the second relies on actin remodeling by small GTPase Rac1 - LIMK1 (LIM-kinase 1). Simple experimental model systems such as Drosophila help probe the causes and consequences leading to human neurocognitive pathologies. Recently, we have developed a Drosophila model for Williams-Beuren Syndrome (WBS): a mutant agnts3 of the agnostic locus (X:11AB) harboring the dlimk1 gene. The agnts3 mutation drastically increases the frequency of ectopic contacts (FEC) in specific regions of intercalary heterochromatin, suppresses learning/memory and affects locomotion. As is shown in this study, the polytene X chromosome bands in reciprocal hybrids between agnts3 and the wild type strain Berlin are heterogeneous in modes of FEC regulation depending either on maternal or paternal gene origin. Bioinformatic analysis reveals that FEC between X:11AB and the other X chromosome bands correlates with the occurrence of short (~30 bp) identical DNA fragments partly homologous to Drosophila 372-bp satellite DNA repeat. Although learning acquisition in a conditioned courtship suppression paradigm is similar in hybrids, the middle-term memory formation shows patroclinic inheritance. Seemingly, this depends on changes in miR-974 expression. Several parameters of locomotion demonstrate heterosis. Our data indicate that the agnts3 locus is capable of trans-regulating gene activity via POEs on the chromatin nuclear organization, thereby affecting behavior.

[Neurogenetics and Neuroepigenetics].

"Genetics of behavior," or "Neurogenetics," is based on the evolutionary ideas of T. Dobzhansky on brain development and behavior. It continues with the "experimental genetics of higher nervous activity" of I. Pavlov and uses a comparative approach in the study of heredity and variation in behavioral manifestations, from Protozoa to humans. The study of the classical Pavlovian conditioned reflex in mutant Drosophila helped to identify the main types of memory and their evolutionary conservatism. Long-term memory defects are caused by mutations of the same genes as in mental, retardation in humans, when signaling cascades intersecting with the cAMP-dependent pathway are damaged. The cascade of actin remodeling is also among these. The key enzyme, LIM-kinase 1, controls cognitive manifestations of the "genomic disease" Williams deletion syndrome. Its study resulted in the recognition of neuroepigenetics as an interface between the genome and environmental influences. Epigenetic factors of "variability"--DNA methylation, histone acetylation, and microRNA regulation--do not change the structure of the gene but its manifestations. Certain miRNAs have already been considered to be both biomarkers for neurodegenerative diseases and factors of the intergenerational transmission of the behaviorial properties of ancestors who experienced stress from adverse environmental influences.

[Learning and memory in Drosophila: physiologic and genetic bases].

Elucidation of molecular mechanisms of cognitive functions is one of the major achievements in neurobiology. At most, this is due to the studies on the simple nervous systems, such as the CNS in Drosophila melanogaster. Many of its functional characteristics are pretty similar to higher vertebrates. Among these are: 1) evolutionary conservation of genes and molecular systems involved in the regulation of learning acquisition and memory formation; 2) presence of highly specialized and differentiated sensory, associative and motor centers; 3) utilization of similar modes of informational coding and analysis; 4) availability of major learning forms including non-associative, as well as associative learning; 5) diversity of different memories, including short-term- and protein synthesis- dependent long-term memory; 6) presence of aminergic reinforcement systems in the brain; 7) feed-back loops of circadian clocks, current organism experience and individual organism characters affecting cognitive process per se. In this review the main attention is paid to the two mostly studied Drosophila learning forms, namely to olfactory Iearning and courtship suppression conditioning (CCS). A separate consideration is given to the impacts of kynurenins and metabolite of actin remodeling signal cascade.

[Effect of heat shock on courtship behavior, sound production, and learning in comparison with the brain content of LIMK1 in Drosophila melanogaster males with altered structure of the LIMK1 gene].

In this paper we present results of a comprehensive analysis of the effect of heat shock at different stages of ontogenesis (adult stage, development of the mushroom bodies and the central complex) on courtship behavior (latency, duration and efficacy of courtship), sound production (pulse interval, dispersion of interpulse interval, the percentage of distorted pulses, the mean duration of the pulse parcels), learning and memory formation compared with the content of isoforms LIMK1 in Drosophila melanogaster male with altered structure of the limk1 gene. The heat shock is shown to affect the behavior parameters and LIMK1 content in analyzed strains of Drosophila. The most pronounced effect of the heat shock was observed at the stage of development of the central complex (CC). Heat shock at CC and adult restores the ability of learning and memory formation in the mutant strain agn(ts3), which normally is not able to learn and form memory. Correlations between changes of content of isoforms LIMK1 and behavioral parameters due to heat shock have not been established.

The Drosophila agnostic Locus: Involvement in the Formation of Cognitive Defects in Williams Syndrome.

The molecular basis of the pathological processes that lead to genome disorders is similar both in invertebrates and mammals. Since cognitive impairments in Williams syndrome are caused by LIMK1 hemizygosity, could the spontaneous and mutant variants of the Drosophila limk1 gene serve as a model for studying two diagnostic features from three distinct cognitive defects of the syndrome? These two symptoms are the disturbance of visuospatial orientation and an unusualy strong fixation on the faces of other people during pairwise interaction with a stranger. An experimental approach to the first cognitive manifestation might be an analysis of the locomotor behavior of Drosophila larvae involving visuospatial orientation during the exploration of the surrounding environment. An approach to tackle the second manifestation might be an analysis of the most natural ways of contact between a male and a female during courtship (the first stage of this ritual is the orientation of a male towards a female and following the female with constant fixation on the female's image). The present study of locomotor activity and cognitive repertoire in spontaneous and mutant variants of the Drosophila agnostic locus allows one to bridge alterations in the structure of the limk1 gene and behavior.

Williams syndrome as a model for elucidation of the pathway genes - the brain - cognitive functions: genetics and epigenetics.

Genomic diseases or syndromes with multiple manifestations arise spontaneously and unpredictably as a result of contiguous deletions and duplications generated by unequal recombination in chromosomal regions with a specific architecture. The Williams syndrome is believed to be one of the most attractive models for linking genes, the brain, behavior and cognitive functions. It is a neurogenetic disorder resulting from a 1.5 Mb deletion at 7q11.23 which covers more than 20 genes; the hemizigosity of these genes leads to multiple manifestations, with the behavioral ones comprising three distinct domains: 1) visuo-spatial orientation; 2) verbal and linguistic defect; and 3) hypersocialisation. The shortest observed deletion leads to hemizigosity in only two genes: eln and limk1. Therefore, the first gene is supposed to be responsible for cardiovascular pathology; and the second one, for cognitive pathology. Since cognitive pathology diminishes with a patient's age, the original idea of the crucial role of genes straightforwardly determining the brain's morphology and behavior was substituted by ideas of the brain's plasticity and the necessity of finding epigenetic factors that affect brain development and the functions manifested as behavioral changes. Recently, non-coding microRNAs (miRs) began to be considered as the main players in these epigenetic events. This review tackles the following problems: is it possible to develop relatively simple model systems to analyze the contribution of both a single gene and the consequences of its epigenetic regulation in the formation of the Williams syndrome's cognitive phenotype? Is it possible to use Drosophila as a simple model system?

[Expression of the Drosophila melanogaster limk1 gene 3'-UTRs mRNA in Yeast Saccharomyces cerevisiae].

The stability of mRNA and its translation efficacy in higher eukaryotes are influenced by the interaction of 3'-untranscribed regions (3'-UTRs) with microRNAs and RNA-binding proteins. Since Saccharomyces cerevisiae lack microRNAs, it is possible to evaluate the contribution of only 3'-UTRs' and RNA-binding proteins' interaction in post-transcriptional regulation. For this, the post-transcriptional regulation of Drosophila limk1 gene encoding for the key enzyme of actin remodeling was studied in yeast. Analysis of limkl mRNA 3'-UTRs revealed the potential sites of yeast transcriptional termination. Computer remodeling demonstrated the possibility of secondary structure formation in limkl mRNA 3'-UTRs. For an evaluation of the functional activity of Drosophila 3'-UTRs in yeast, the reporter gene PHO5 encoding for yeast acid phosphatase (AP) fused to different variants of Drosophila limk1 mRNA 3'-UTRs (513, 1075, 1554 bp) was used. Assessments of AP activity and RT-PCR demonstrated that Drosophila limkl gene 3'-UTRs were functionally active and recognized in yeast. Therefore, yeast might be used as an appropriate model system for studies of 3'-UTR's role in post-transcriptional regulation.

[Analysis of intermolecular interaction energy inputs in benzene-imidazole and imidazole-imidazole systems in parallel displaced and T-configuration].

Intermolecular interactions in several dimer aromatic systems were analyzed to determine how various energy contributions (electrostatic, exchange, repulsion, and polarization) change depending on the value of monomers separation. Different contributions to the intermolecular energy interactions between imidazole-imidazole and benzene-imidazole dimers are studied using the aug-cc-pVDZ basis set in the framework of ab initio Hartree-Fock and second-order Møller-Plesset perturbation theory methods. Special attention is paid to the exchange and dispersion energy binding contributions.

Initiation of the 3':5'-AMP-induced protein kinase A Iα regulatory subunit conformational transition. Part I. A202 and A326 are critical residues.

Protein-ligand docking and molecular dynamics studies have shown that the key event initiated by 3':5'-AMP binding to the A- and B-domains of protein kinase A Iα regulatory subunit is formation of a hydrogen bond between 3':5'-AMP and A202(A326) (the residue in parentheses being from the B-domain). The A202(A326) amide group movement associated with the bond formation leads to reorganization of the phosphate binding cassette (PBC) (the short 3(10)-helix becomes the long α-helix). This process results in L203(L327) displacement and finally causes hinge (B-helix) rotation. The L203(L327) displacement and packing into the hydrophobic pocket formed by the PBC and ß2ß3-loop also depends on the ß2ß3-loop conformation. The correct conformation is maintained by R, I, E, but not K at position 209(333) of the A- and B-domains. So, the R209K and R333K mutants have problems with reaching B-conformation. The apo-form of the 3':5'-AMP-binding domain also undergoes transition from H- to B-conformation. In this case, the movement of A202(A326) amide group seems to be a result of reorganization of the PBC into a more stable α-helix.

Initiation of the 3':5'-AMP-induced protein kinase A Iα regulatory subunit conformational transition. Part II. Inhibition by Rp-3':5'-AMPS.

Protein-ligand docking and ab initio calculations have shown that the 3':5'-AMP phosphorothioate analog (Rp-3':5'-AMPS) blocks the A326 amide group displacement typical of transition from the H- to B-conformation within the B-domain of protein kinase A Iα R-subunit. This behavior of Rp-3':5'-AMPS leads to the inhibition of initial stages of hydrophobic relay operation. In accordance with the proposed hypothesis, Rp-3':5'-AMPS similarly to 3':5'-AMP forms a hydrogen bond with the amide group of A326; however, the properties of this bond together with the position of the sulfur atom prevent the movement of A326. Finally, the Rp-3':5'-AMPS-bound domain appears to be locked in the H-conformation, which is in agreement with the X-ray data.

[Participation of GDNF, LIMK1 signal pathways and heat shock proteins in processes of Drosophila learning and memory formation].

Molecular mechanisms of the synapse and dendrite maintenance and their disturbance in psychiatric and neurodegenerative diseases (ND) are intensively studied in searching for target genes of therapeutic actions. It is suggested that glia, alongside with well-studied pre- and postsynaptic neurons, is the third, poorly studied partner in synaptic transmission (the tripartite synapse) that is involved in the positive feedback between the first two partners. This bidirectional coupling between presynaptic neurons and their postsynaptic targets involve neurotrophins (NTF), such as glial cell-derived neurotrophic factor (GDNF) that is produced LIM kinase 1 (LIMK1, the key enzyme of actin remodeling). The cytoplasmic domain of neuregulins interacts with LIMK1. Since neurons and axons that do not receive a sufficient NTF amount are at risk of degeneration and synapse elimination, GDNF seems to be the best studied factor of the ND therapy. The delivery of GDNF stem cells to the neurodegeneration locus is very efficient. There has been proposed a new approach based on use of Drosophila heat shock (hs) promoter. This promoter responds to the mammalian body temperature as to the shock factor resulting in the constant expression of the GDNF gene. The Drosophila models allow studying any given component of the bidirectional communication between pre- and postsynaptic neurons in development of the main diagnostic ND symptom, such as defective memory resulted from synaptic atrophy. In the present study we used the Drosophila stocks imitating different disturbances of the nervous system: Canton-S (wild type), GDNF (transgenic flies that carry human glial-cell-line derived nerve factor (GDNF) gene under hs promoter), l(1)ts403 with dusturbance of HSPs mRNA extranuclear transport, a defect of intracellular stress report, and agn(ts3) mutation in LIMK1 gene. We have revealed functional connections at the behavioral level (learning/memory) depending on the GDNF and LIMK1 brain expression and HSPs transduction that might provide targets for complex approaches for the ND treatment.

[Behavioral and molecular effects of endogenic kynurenines deficit in the honeybee (Apis mellifera L.)].

The importance of tryptophan endogenous metabolites kynurenines in the long-term memory and functioning of the signal cascade GluR - LIMK1 - F-actin, mediating the long-term memory trace storage, was demonstrated. The deficit of kynurenines induced by allopurinol (tryptophanoxygenase inhibitor) suppressed the long-term memory, decreased the LIMK1 expression, and paradoxically increased the F-actin content in the honeybee brain. These data agree with the earlier findings in drosophila mutant vermilion (the mutation of tryptophanoxygenase gene).

Thermodynamic analysis of protein kinase A Ialpha activation.

Thermodynamic analysis of protein kinase A (PKA) Ialpha activation was performed using Quantum 3.3.0 docking software and a Gaussian 03W quantum mechanical computational package. Expected stacking interactions between adenine of 3':5'-AMP and aromatic moieties of amino acids were taken into account by means of MP2/6-31G(d) IPCM (isodensity polarizable continuum model) computations (epsilon = 4.0). It is demonstrated that thermodynamically favorable agonist-induced PKA Ialpha activation is mediated by two processes. First, 3':5'-AMP binding is accompanied by structural changes leading to a thermodynamically favorable regulatory subunit conformation, which is hardly realized in the absence of the ligand (DeltaG degrees (R) = -23.9 +/- 8.2 kJ/mol). Second, 3':5'-AMP affinity to the regulatory subunit conformation observed after agonist-induced PKA Ialpha activation is higher than that to inactive holoenzyme complex (DeltaG degrees (3':5'-AMP) = -28.1 +/- 9.7 kJ/mol). ATP is capable of docking into the 3':5'-AMP-binding site B of the regulatory subunit complexed with the catalytic one, resulting in inhibition of kinase activation. True constants of 3':5'-AMP binding to PKA Ialpha holoenzyme were found to be 60 and 57 microM for the regulatory subunit domains A and B, respectively. These constants, unlike the binding equilibrium constant determined using established experimental techniques and ranging from 15 nM to 2.9 microM, are proved to be direct measures of 3':5'-AMP-PKA Ialpha binding affinity. Their values are in a reasonable agreement with the changes in 3':5'-AMP concentration in the cell (2-55 microM) and account for PKA Ialpha activation in response to adequate stimuli.

Molecular mechanisms of imidazole and benzene ring binding in proteins.

Aromatic bonds of amino acid radicals play an important role in arrangement of protein primary structure. Previously, the existence of a number of preferable conformations of aromatic dimers was shown theoretically and experimentally, the best known of which are parallel-displaced and perpendicular T conformations. To reveal principles that define preference of various conformations for His-His and Phe-His dimers, non-empirical quantum-chemical calculations of diimidazole and benzene-imidazole were carried out. Calculations were performed using the 6-31G** basis with account for electronic correlations in frames of MP2 and MP4 methods of perturbation theory. Comparative analysis of energetic and geometric parameters of the systems points to the preference of stacking contact or classical hydrogen bond in diimidazole. On the contrary, T conformation is maximally advantageous for benzene-imidazole.

[Courtship behavior, communicative sound production and resistance to stress in Drosophila mutants with defective agnostic gene, coding for LIMK1].

To elucidate the role of one of the main elements of signal cascade of actin remodeling--LIM-kinase 1 (LIMK1)--in the control of animal behavior we studied the characteristics of courtship behavior, parameters of acoustic communicative signals and their resistance to heat shock (HS, 37 degrees C, 30 min) in Drosophila melanogaster males from the strain with mutation in locus agnostic (agn(ts3)) containing gene CG1848 for LIMK1. The data obtained was compared with the results of our previous similar investigation on wild type CS males (Popov et al., 2006). Flies were divided into 4 groups. The males of control groups were not subjected to heat shock. The rest of males were subjected to heat shock either at the beginning of larval development when predominantly mushroom body neuroblasts are dividing (groups HS1), or at the prepupal stage when the brain central complex is developing (groups HS2), or at the imago stage one hour before the test (groups HS3). All males were tested at the age of 5 days. Virgin and fertilized CS females were used as courtship objects. Comparison of control groups of the two strains--CS and agnostic--have shown that the mutation agn(ts3) has no influence on the main parameters of courtship behavior of intact (not subjected to HS) males (courtship latency, the rapidity of achieving copulation, courtship efficiency) but leads to lowering of their sexual activity, increase of duration of sound trains in the songs and to slight increase of rate and stability of working of singing pacemakers. Agnostic males in comparison to wild type males are more resistant to HS given 1 hour before the test. After HS their courtship intensity does not decrease and the main parameters of their courtship behavior and communicative sound signals in comparison tu wild type males either do not change, or appear to be even better stabilized. The frequency of distorted sound pulses (an indicator of frequency of impairments in the activity pattern of neuro-motor circuits of the singing center) decreases, and the rate and stability of pacemakers of the pulse and the sine songs increases. So, the sharply elevated LIMK1 and p-cofilin concentrations in the cells of agn(ts3) mutants, in comparison to wild type males, leading to derangement of learning and memory (Medvedeva et al., 2008) are accompanied by decline of motivation of males but do not seriously influence the neuro-motor coordination during singing. The higher resistance of characterictics of their behavior and communicative sound signals to heat shock is in agreement with the fact that the extremely high LIMK1 and P-cofilin concentrations in their cells go down to normal values after HS. At the same time the amyloid aggregations disappear and normally defective learning and memory are restore.

[Effect of mutation-induced excess brain concentration of intermediates of the kynurenine pathway of tryptophan metabolism on stress resistance and courtship behavior and communicative sound production in male Drosophila melanogaster].

The resistance of courtship behavior and communicative sound production to heat shock (37 degrees C, 30 min) was studied in wild-type Canton S (CS) male Drosophila melanogaster and males of two strains with defects in the kynurenine pathway of tryptophan metabolism (KPTM) caused by mutations cinnabar (block at the level of kynurenine-3-hydroxylase leading to accumulation of kynurenic acid, a neuroprotective metabolite, in the brain) and cardinal (block at the level of phenoxazinone synthetase causing accumulation of 3-hydroxykynurenine, an oxidative stress generator, in the brain). Males of each strain were divided into four groups. Males from control groups were not exposed to heat shock. The other groups were exposed to heat shock at the late embryonic/early larval (the first instar) developmental stage, when mushroom bodies are formed (HS1 groups); at the prepupal stage, when the brain central complex develops (HS2 groups); or at the imago stage 1 h before the experiment (HS groups). All males were tested at an age of five days. Virgin and fertilized five-day-old CS females served as courtship objects. The courtship behavior and singing of control CS and cinnabar males were similar. Control cardinal males also had high motivation, but their courtship efficiency was lower because of less precise movements (wing vibration was often not accompanied by sound production) and hyperexcitability. Exposure of first-instar larvae to heat shock had almost no effect on behavior or singing of adult males of any strain. In cardinal males exposed to heat shock at the prepupal stage or, especially, at the imago stage 1 h before the test (the HS2 and HS groups), courtship was strongly impaired, and various distortions appeared in their sound signals, which indicated disturbance of coordination between elements of the song center and their interaction with pacemakers. These effects were much milder or absent altogether in HS2 and HS wild-type males and, especially, cinnabar males. Thus, permanent excess of 3-hydroxykynurenine in the male brain dramatically decreased their stress resistance. In contrast, excess of kynurenic acid alleviated the consequences of stress.

[Systemic regulation of genetic and cytogenetic processes by a signal cascade of actin remodeling: locus agnostic in Drosophila].

The concept on systemic regulation of genetic and cytogenetic processes has acquired a new perspective after the completion of the Human Genome project, when the view on systemic realization of genetic activity in the dynamic spatial organization of the genome is the nucleus was generally accepted. This organization underlies plasticity of complex biological systems. Chromosome position within the nucleus determined both processes of normal development and the development of genomic diseases, i.e., changes according to the environmental requirements, current needs of the organism, and its individual experience. Nuclear actin has been envisioned as a main factor bridging three levels of the genome organization (nucleotide, structural, and spatial), due to its capability of (1) regulating transcription by activating all three classes of RNA polymerase; (2) participating in chromatin remodeling by interacting with numerous proteins; and (3) lining the nuclear membrane, determining the chromosome attachment points and regulating export from the nucleus. In view of this, the role of actin remodeling factors (LIMK1, cofilin, actin) in the development of neurodegenerative diseases, including prionic ones, and in the mechanisms of generation of genomic diseases, syndromes resulting from unequal recombination, has been intensely studied. Drosophila is a helpful model organism to determine the sequence of events in this system of hierarchical relationships. Using spontaneous and mutant variants of the agnostic locus, we have designed a model of the Williams syndrome, which also reproduces main diagnostic traits of neurodegenerative diseases.

[The role of stacking interactions in the mechanisms of binding of the glycine site of NMDA-receptor with antagonists and 3-hydroxykynurenine].

Ab initio quantum chemical calculations of benzene dimer, benzene dimer with 5,7 clorination of one aromatic ring, 3-hydroxykynurenine, and kunurenic acid molecules situated above Phe484 aromatic ring of receptor binding site fragment were carried out in order to investigate the role of stacking interaction in the binding of agonists and antagonists with the glycine site of the NMDA receptor NR1 subunit. All calculations were done with the help of GAMESS 6.4 software with 6-31G** atomic gaussian basal functions with complete optimization of geometry and taking into account the electron correlation up to the second-order Moller-Plesset perturbation theory. It was shown that the parallel dislodged conformations of the benzene dimer is energetically most advantageous. Successive substitution of chlorine atoms for the protons of one aromatic ring in 7 and 5 positions leads to an increase in stacking-interaction energy and a mutual displacement of aromatic rings. In the case of kunurenic acid and its derivatives, which are NMDA receptor antagonists, the increase in the energy of stacking interactions leads to the strengthening of inhibition of the ion channel, whereas the 3-hydroxykynurenine molecule is neither agonist, nor antagonist for the glycine site of the NMDA receptor due to the sterical constraints.

Comparative analysis of the locations of the NR1 and NR2 NMDA receptor subunits in honeybee (Apis mellifera) and fruit fly (Drosophila melanogaster, Canton-S wild-type) cerebral ganglia.

The locations of the NR1 and NR2 subunits of the GABA receptor were studied in brain structures in insects--honeybees and fruit flies--using an immunohistochemical method. The specificities of the antibodies to the NR1 and NR2 subunits were confirmed by the antisense knockdown method for the NR1 subunit and western blotting. The data obtained here lead to the conclusion that the distributions of the NR1 and NR2 subunits of the NMDA receptor complex in the cerebral ganglia of the honeybee and fruit fly are similar; areas with the highest concentrations of NR1 and NR2 subunits were identified, and these were found to be different in the different insects. This is associated with the behavioral characteristics of these two insect species.