Molecular correlates of emotional learning using genetically selected rat lines

The genetic contributions to active avoidance learning in rodents have been well established, yet the molecular basis for genetically selected line differences remains poorly understood. To identify candidate genes influencing this active avoidance paradigm, we utilized the bidirectionally selected Syracuse high- and low-avoidance (SHA and SLA) rat lines that markedly differ in their two-way active avoidance behavior. Rats were phenotyped, rested to allow recovery from testing stress and then hippocampi were dissected for gene expression profiling (Affymetrix U34A chips; approximately 7000 known genes), comparing SLA to SHA. Next, a subset of differentially expressed genes was confirmed by real-time PCR (RT-PCR) in hippocampi. Additional studies at the protein level were performed for some genes. Using triplicate arrays on pooled hippocampal samples, differentially expressed genes were identified by microarray suite 5.0 and robust multi-array average analyses. By RT-PCR analysis in hippocampi, eight genes were nominated as potential candidate genes consistent with the differential expression from the microarray data. Four genes, Veli1 (mlin-7B), SLC3a1, Ptpro and Ykt6p, showed higher expression in SHA hippocampi than SLA. Four genes, SLC6A4, Aldh1a4, Id3a and Cd74, showed higher expression in SLA hippocampi than SHA. The active avoidance behavioral difference between lines probably emerges from 'many small things'. These potential candidate genes generate hypotheses for future testing in human association and rodent studies. Differences in levels of a pleiotropic gene like Ptpro and SLC6A4 suggest that small differences over a lifespan may contribute to large behavioral differences.

Genetic differences in the tail-suspension test and its relationship to imipramine response among 11 inbred strains of mice

BACKGROUND

The tail suspension test (TST) is a simple screening test for the behavioral effects of antidepressants in rodents. This experiment investigated the interindividual differences in responses to stressful situations measured by duration of immobility in the TST and the effects of imipramine (30 mg/kg intraperitoneally) in reducing immobility among 11 inbred strains of mice. The 11 inbred strains were 129S6/SvEvTac, A/J, AKR/J, Balb/cJ, C3H/HeJ, C57BL/6J, DBA/2J, FVB/NJ, NMRI, SencarA/PtJ, and SWR/J.

METHODS

All mice underwent two trials of TST: 1) spontaneous, basal TST and 2) imipramine or saline TST. The duration of immobility was the trait measured during a 6-min test.

RESULTS

In the four strains tested, female mice had longer duration of immobility than male mice in basal TST duration of immobility. For male mice (n = 11 strains), significant strain differences in immobility duration were found for both basal TST and imipramine response TST, with heritability estimates of .31 and .60, respectively. Immobility duration for the DBA/2J, FVB/NJ, and NMRI strains were significantly reduced by imipramine, relative to saline. Surprisingly, this reduction of immobility by imipramine was independent of the basal immobility.

CONCLUSIONS

These results suggest that the responses on basal TST and the imipramine-mediated responses on TST are mediated by separate genetic pathways.

Absence of a significant linkage between Na+,K+-ATPase subunit (ATP1A3 andATP1B3) genotypes and bipolar affective disorder in the old-order Amish

Previous studies provide evidence for a genetic component for susceptibility to bipolar affective disorder (BPAD) in the old-order Amish population. El-Mallakh and Wyatt [1995: Biol Psychiatry 37:235-244] have suggested that the Na(+),K(+)-ATPase may be a candidate gene for BPAD. This study examines the relationship between BPAD in the old-order Amish cohort and the Na(+),K(+)-ATPase alpha1 and beta3 subunit genes (ATP1A3, ATP1B3). A total of 166 sibling pairs were analyzed for linkage via nonparametric methods. Suggestive levels of statistical significance were not reached in any stratification model for affective illness. Overall, the results do not support linkage of bipolar disorder to the Na(+),K(+)-ATPase alpha subunit gene (ATP1A3) and beta subunit gene (ATP1B3) in these old-order Amish families and they show that these Na(+),K(+)-ATPase subunit genes are not major effect genes (>or=fourfold increased genetic risk of disease) for BPAD in the old-order Amish pedigrees. We cannot exclude other genetic variants of the Na(+),K(+)-ATPase hypothesis for BPAD, whereby other loci may modifying Na(+),K(+)-ATPase activity.

The effects of leptin on REM sleep and slow wave delta in rats are reversed by food deprivation

Leptin (ob protein) is an adipose tissue derived circulating hormone that acts at specific receptors in the hypothalamus to reduce food intake. The protein is also critically involved in energy balance and metabolic status. Here the effect of leptin on sleep architecture in rats was evaluated because food consumption and metabolic status are known to influence sleep. Sprague-Dawley rats were chronically implanted with electrodes for EEG and EMG recording and diurnal sleep parameters were quantified over 9-h periods following leptin administration. Murine recombinant leptin (rMuLep) was administered systemically to rats that either had undergone 18 h of prior food deprivation or had received food ad libitum. In the normally fed rats, leptin significantly decreased the duration of rapid eye movement sleep (REMS) by about 30% and increased the duration of slow wave sleep (SWS) by about 13%, the latter effect reflecting enhanced power in the delta frequency band. These results are consistent with studies that have linked changes in metabolic rate with effects on sleep. Leptin administration has previously been shown to alter neuroendocrine parameters that could have mediated these changes in sleep architecture. Unexpectedly, prior food deprivation negated the effect of leptin on both REMS and SWS, a result that emphasizes the significance of the apparent coupling between sleep parameters and energy status.

Mapping quantitative trait loci for seizure response to a GABAA receptor inverse agonist in mice

To define the genetic contributions affecting individual differences in seizure threshold, a beta carboline [methyl-beta-carboline-3-carboxylate (beta-CCM)]-induced model of generalized seizures was genetically dissected in mice. beta-CCM is a GABAA receptor inverse agonist and convulsant. By measuring the latency to generalized seizures after beta-CCM administration to A/J and C57BL6/J mice and their progeny, we estimated a heritability of 0.28 +/- 0.10. A genome wide screen in an F2 population of these parental strains (n = 273) mapped quantitative trait loci (QTLs) on proximal chromosome 7 [logarithm of the likelihood for linkage (LOD) = 3.71] and distal chromosome 10 (LOD = 4.29) for seizure susceptibility, explaining approximately 22 and 25%, respectively, of the genetic variance for this seizure trait. The best fitting logistic regression model suggests that the A/J allele at each locus increases the likelihood of seizures approximately threefold. In a subsequent backcross population (n = 223), we mapped QTLs on distal chromosome 4 (LOD = 2.88) and confirmed the distal chromosome 10 QTLs (LOD = 4.36). In the backcross, the C57BL/6J allele of the chromosome 10 QTL decreases the risk of seizures approximately twofold. These QTLs may ultimately lead to the identification of genes influencing individual differences in seizure threshold in mice and the discovery of novel anticonvulsant agents. The colocalization on distal chromosome 10 of a beta-CCM susceptibility QTL and a QTL for open field ambulation and vertical movement suggests the existence of a single, pleiotropic locus, which we have named Exq1.

Towards a genetics of anxious temperament: from mice to men

An enduring question in the study of human personality is 'to what extent and how do genetic factors influence such personality constructs as "trait anxiety"?'. We selectively survey progress and obstacles in the genetic dissection of fear-like behavior, especially as it pertains to more constitutional forms of anxiety or anxious temperament. We emphasize the selection of phenotypic dimensions and the utility of 'temperament' and personality constructs as mediating variables for psychopathology. We summarize studies on the use of mouse models of 'anxious temperament' to map genetic loci, and briefly review recent genetic association studies of related phenotypes in humans utilizing candidate genes. We suggest that further progress in genetic research on 'trait anxiety' disorders may come from the following: (i) developing alternate constructs for investigating psychiatric illness focusing on dimensional scales, mediating variables and premorbid traits; (ii) examining 'at-risk' populations for protective genetic factors influencing 'resilience' or loci providing a reduced risk of a given trait or disorder; and (iii) utilizing lower animal models as a bridge to dissect the genetic factors contributing to related human phenotypes.

Mapping quantitative trait loci for fear-like behaviors in mice

Two mouse models developed for screening anxiolytic drugs were selected for genetic analysis, namely "wall-seeking" tendency in an open field ("thigmotaxis") and the light-to-dark transition (LD) paradigm, a conflict test. These tests measure differences in naturalistic tendencies of mice to explore a novel environment and to avoid a bright light or the center of an open field. In an F2 intercross of two strains of mice (A/J and C57BL/6J) that differ markedly in these behaviors, we estimated a broad sense heritability ranging from 0.3 to 0.59. With this intercross (n = 518), we have mapped several quantitative trait loci (QTL) for these behaviors by performing a genome-wide search. A significant QTL on chromosome 10 (near D10Mit237; LOD of 9.3) that affects LD behavior was identified, and suggestive QTL (LOD > 2.8) were mapped to chromosomes 6, 15, 19, and X. For center time behaviors, QTL were identified on chromosome 1 (LOD of 7.7 and 4.0 for the initial 5-min epoch and the first trial average of the next two 5-min epochs, respectively), and suggestive QTL (LOD > 2.8) were mapped to chromosomes 6 and 14. These QTL individually explain from 2.3 to 8.4% of the phenotypic variance. Collectively, the multiple independent QTL explain from 3.5 to 26.5% of the F2 population's phenotypic variance, depending on the trait. The complexity and heterogeneity of the genetic factors underlying these fear-like behaviors are illustrated by the lack of shared QTL between paradigms and by mapping different QTL for repeated trials of behavior. The identification of QTL affecting individual differences in fear-like behavior may lead to the identification of new gene products and pathways that modulate behavior, providing targets for rational drug design.

Mapping quantitative trait loci for open-field behavior in mice

By performing a whole genome screen in an F2 intercross of two strains of mice (A/J and C57BL/6J), which differ markedly in their behavioral response to a brightly lit open field (O-F), we have mapped several quantitative trait loci (QTL) for this complex behavioral phenotype. QTL on chromosomes 1 and 10 were identified that affect both initial ambulation in the O-F (initial "response to novelty" ambulation) (lod of 7.1 and 8.8, respectively) and vertical rearings (lod of 4.5 and 8.5, respectively). For habituated O-F behavior, QTL were identified on chromosomes 3 and 10 for ambulation (lod of 4.1 and 14.7, respectively) and on chromosomes 1, 10, and 19 for vertical rearings (lod of 5.8, 6.0, and 4.7, respectively). The QTL on chromosome 1 (near D1Mit116; 101 cM) was specific for initial O-F ambulation behavior, whereas the QTL on chromosome 10 (near D10Mit237; 74 cM) affected both initial and habituated rearing behavior. Additional suggestive QTL (lod, > 2.8) were mapped to chromosomes 1, 8, 11, 15, and 19. The QTL on chromosomes 1, 10, and 19 individually explain from 3.2 to 12.7%. Collectively, the multiple independent QTL explain from 16.3 to 24.1% of the F2 population's phenotypic variance, depending on the trait. These identified QTL should prove useful for dissecting the genetic and behavioral dimensions of O-F behavior, fostering an understanding of individual differences.

Genomic organization of the mouse granzyme A gene. Two mRNAs encode the same mature granzyme A with different leader peptides

Granzyme A is a serine protease that, together with the other granular components of cytotoxic T lymphocyte (CTL) cells, has been implicated in the cytolysis process. We report here two different messages and the genomic organization of the mouse granzyme A gene. The granzyme A gene is composed of six exons spanning 7 kilobases. Alternative splicing of the second exon results in the two transcripts. The two mRNA species encode the same mature granzyme A protein but with different leader sequences. The first (HF1) encodes a typical leader signal sequence similar to other granzymes, but the second (HF2) putative leader sequence is different and less hydrophobic. Both messages are present in cultured CTL cell lines and in normal lymphoid tissues. They are both induced when CTL cells are activated in vitro or in vivo. Both messages can be translated in vitro, although the HF1 message appears to be much more efficient as a template. The putative 5' promoter region of the HF gene sequenced (500 base pairs of upstream sequences) contains no well defined promoter sequences aside from the TATA box. The results suggest that (a) granzyme A may be produced with putative different leader sequences from two different mRNAs; (b) this may provide a model system for studying alternate splicing and the evolution of a complex enzymatic system in an organelle; and (c) the genomic DNA reported will be useful for studying transcription regulations involved in controlling the specific expression pattern of this gene.

IL-2 induces expression of serine protease enzymes and genes in natural killer and nonspecific T killer cells

The expression of serine protease genes was examined in murine NK cells that were purified by panning spleen cells with PMA. Although unstimulated NK cells were cytolytic, they were found not to express the C11 (chymotrypsin-like) mRNA. Culturing these cells in IL-2 (500 to 800 U/ml) for 5 to 7 days induced both the lytic activities and the protease enzymes by 20- to 30-fold. Concomitant to these activation events, the total steady state mRNA of both C11 and HF (trypsin-like) genes were also elevated. The activation of lysis, serine protease enzymes, and C11 and HF mRNA all peaked around day 5 in culture and was dose dependent. In order to exclude the possibility that PMA synergizes with IL-2 in this system, spleen cells from SCID mice, which contained mainly NK cells, were cultured under the same conditions (800 U/ml IL-2, with or without PMA) and PMA did not appear to enhance the expression of these mRNA. Similarly, IL-2 also induced the lytic activities, enzyme levels, and mRNA in the non-Ag-specific T killer cells isolated from spleens of normal mice. Lytic activity of T killer cells was not as high as the NK cells, however, the addition of PHA into the lytic assay resulted in enhanced lysis comparable to that of NK cells. These results showed that lytic activity increased along with protease enzyme levels and mRNA expression in both NK and resting T cells. Therefore, elevated levels of the protease enzymes could be one mechanism involved in optimal lytic activity of IL-2-induced lymphokine activated killer cells.

IL-2 induces expression of serine protease enzymes and genes in natural killer and nonspecific T killer cells

The expression of serine protease genes was examined in murine NK cells that were purified by panning spleen cells with PMA. Although unstimulated NK cells were cytolytic, they were found not to express the C11 (chymotrypsin-like) mRNA. Culturing these cells in IL-2 (500 to 800 U/ml) for 5 to 7 days induced both the lytic activities and the protease enzymes by 20- to 30-fold. Concomitant to these activation events, the total steady state mRNA of both C11 and HF (trypsin-like) genes were also elevated. The activation of lysis, serine protease enzymes, and C11 and HF mRNA all peaked around day 5 in culture and was dose dependent. In order to exclude the possibility that PMA synergizes with IL-2 in this system, spleen cells from SCID mice, which contained mainly NK cells, were cultured under the same conditions (800 U/ml IL-2, with or without PMA) and PMA did not appear to enhance the expression of these mRNA. Similarly, IL-2 also induced the lytic activities, enzyme levels, and mRNA in the non-Ag-specific T killer cells isolated from spleens of normal mice. Lytic activity of T killer cells was not as high as the NK cells, however, the addition of PHA into the lytic assay resulted in enhanced lysis comparable to that of NK cells. These results showed that lytic activity increased along with protease enzyme levels and mRNA expression in both NK and resting T cells. Therefore, elevated levels of the protease enzymes could be one mechanism involved in optimal lytic activity of IL-2-induced lymphokine activated killer cells.

A T cell- and natural killer cell-specific, trypsin-like serine protease. Implications of a cytolytic cascade

A new trypsin-like serine protease was cloned from both a murine cytotoxic T lymphocyte and a human PHA-stimulated peripheral blood lymphocyte cDNA library. In both the mouse and human system, this transcript had a T cell- and NK-specific distribution, being detected in cytotoxic T lymphocytes (CTL), some T-helper clones, and NK, but not in a variety of normal tissues. T-cell activation with Con A plus IL-2 induced mouse spleen cells to express this gene with kinetics correlating with the acquisition of cytolytic capacity. Both the mouse and human nucleotide sequences of this gene encoded an amino acid sequence with 25-40% identity to members of the serine protease family. The active-site "charge-relay" residues (His-57, Asp-102, and Ser-195 of the chymotrypsin numbering system) are conserved, as well as the trypsin-specific Asp (position 189 in trypsin). We reviewed the evidence of this serine protease's role in lymphocyte lysis and proposed a "lytic cascade." We discussed the biological and clinical implications of a cascade, proposing these enzymes as markers for cytolytic cells and as targets for rational drug therapy. Genetic and acquired deficits in the lethal hit-delivery system are considered as a basis for approaching some immunodeficiency states, including severe EBV infections, T-gamma leukemias, and T8+ lymphocytosis syndromes.

A high proportion of T lymphocytes that infiltrate H-2-incompatible heart allografts in vivo express genes encoding cytotoxic cell-specific serine proteases, but do not express the MEL-14-defined lymph node homing receptor

The role of cytotoxic cells in in vivo immune functions such as allograft rejection is unknown. To begin to assess the function of cytolytic cells in vivo we have begun with cytolytic cell-specific functional molecules: we have isolated and characterized cytolytic cell-specific cDNA clones from cytolytic T cell clones, both encoding distinct serine esterases. The HF gene encodes a trypsin-like enzyme while the C11 gene encodes an enzyme with likely specificity for acidic residues. Here we demonstrate, using in situ hybridization with RNA probe, that both genes are expressed selectively in a subset of T lymphocytes that have infiltrated cardiac allografts. The phenotype of these cells is consistent with the most frequent phenotype of active CTL raised in vitro: they are predominantly CD4-, CD8+, MEL-14- T cell blasts. Thus the expression of these genes, each of which encodes serine esterase found in killer cell granules in vitro, is a valid marker for these cells in vivo as well. The kinetics of their accumulation is consistent with, but not proof of, a putative role in allograft rejection. It is likely that HF and C11 gene expression will be of diagnostic value.

Cloning and chromosomal assignment of a human cDNA encoding a T cell- and natural killer cell-specific trypsin-like serine protease

A cDNA clone encoding a human T cell- and natural killer cell-specific serine protease was obtained by screening a phage lambda gt10 cDNA library from phytohemagglutinin-stimulated human peripheral blood lymphocytes with the mouse Hanukah factor cDNA clone. In an RNA blot-hybridization analysis, this human Hanukah factor cDNA hybridized with a 1.3-kilobase band in allogeneic-stimulated cytotoxic T cells and the Jurkat cell line, but this transcript was not detectable in normal muscle, liver, tonsil, or thymus. By dot-blot hybridization, this cDNA hybridized with RNA from three cytolytic T-cell clones and three noncytolytic T-cell clones grown in vitro as well as with purified CD16+ natural killer cells and CD3+, CD16- T-cell large granular lymphocytes from peripheral blood lymphocytes (CD = cluster designation). The nucleotide sequence of this cDNA clone encodes a predicted serine protease of 262 amino acids. The predicted protein has a 22-amino acid presegment, a 6-amino acid prosegment, and an active enzyme of 234 amino acids with a calculated unglycosylated molecular weight of 25,820. The active enzyme is 71% and 77% similar to the mouse sequence at the amino acid and DNA level, respectively. The human and mouse sequences conserve the active site residues of serine proteases--the trypsin-specific Asp-189 and all 10 cysteine residues. The gene for the human Hanukah factor serine protease is located on human chromosome 5. We propose that this trypsin-like serine protease may function as a common component necessary for lysis of target cells by cytotoxic T lymphocytes and natural killer cells.

Cloning of a cDNA for a T cell-specific serine protease from a cytotoxic T lymphocyte

A new serine protease was encoded by a clone isolated from a murine cytotoxic T-lymphocyte complementary DNA library by an RNA-hybridization competition protocol. Complementary transcripts were detected in cytotoxic T lymphocytes, spleen cells from nude mice, a rat natural killer cell leukemia, and in two of eight T-helper clones (both cytotoxic), but not in normal mouse kidney, liver, spleen, or thymus, nor in several tested T- and B-cell tumors. T-cell activation with concanavalin A plus interleukin-2 induced spleen cells to express this gene with kinetics correlating with the acquisition of cytolytic capacity. The nucleotide sequence of this gene encoded an amino acid sequence of approximately 25,700 daltons, with 25 to 35 percent identity to members of the serine protease family. The active site "charge-relay" residues (His57, Asp102, and Ser195 of the chymotrypsin numbering system) are conserved, as well as the trypsin-specific Asp (position 189 in trypsin). A Southern blot analysis indicated that this gene is conserved in humans, mouse, and chicken. This serine protease may have a role in lymphocyte lysis and a "lytic cascade."

Somatic diversification is required to generate the V kappa genes of MOPC 511 and MOPC 167 myeloma proteins

The immune response to phosphocholine in BALB/c mice involves one group of heavy chain variable region (VH) genes and at least three groups of light chain variable region (V kappa) genes, represented by the gene products of the myelomas TEPC 15, MOPC 603, and MOPC 167/MOPC 511. The amino acid sequences of BALB/c myeloma kappa chains MOPC 167 and MOPC 511 are known, and they differ by six amino acids. We have isolated several closely related V region genes of immunoglobulin light chains from a mouse sperm DNA phage library, selecting clones that cross-hybridize with a cDNA plasmid probe encoding the light chain of MOPC 167. We identified six strongly hybridizing clones, representing three separate cloning events. We determined the sequence of the coding and immediate flanking regions of three clones, representing the three separate cloning events, and they proved to be identical. This germ-line sequence encoded the amino acid sequence of neither MOPC 167 nor MOPC 511, but required four base pair changes to generate the V kappa M167 cDNA sequence and five base pair changes to generate the V kappa M511 gene. By Southern hybridization experiments, we demonstrated that neither MOPC 511 nor MOPC 167 germ-line genes exist. We conclude that the V kappa M167 and V kappa M511 genes are created somatically.