Identification of maze learning-associated genes in rat hippocampus by cDNA microarray.

Long-term memory formation requires de novo RNA and protein synthesis. To assess gene-expression changes associated with learning and memory processes, we used cDNA microarray to analyze hippocampal gene expression in male Fischer-344 rats following training in a multiunit T-maze. Here, we report the identification of 28 clones (18 known genes and 10 ESTs) for which expression increased after the maze learning. Some of the known genes appear to be involved in Ca2+ signaling, Ras activation, kinase cascades, and extracellular matrix (ECM) function, which may regulate neural transmission, synaptic plasticity, and neurogenesis. The gene-expression profile presented here provides the groundwork for future, more focused research to elucidate the contribution of these genes in learning and memory processes.

The role of telomerase expression and telomere length maintenance in human and mouse.

The molecular regulation of telomere length has been well elucidated by a series of elegant studies over the past decade. More recently, experimental evidence has accrued that addresses the challenging question of if and how telomere length regulation may contribute to normal human aging or to human disease. Recent studies in mice have provided a mammalian precedent indicating that telomerase deficiency can lead to in vivo dysfunction, most probably as a consequence of progressive telomere shortening. In humans, the evidence that telomere shortening might lead to in vivo dysfunction is far less direct, although the recent description of telomerase deficiency and telomere shortening associated with the DKC syndrome is suggestive of such a link. Methodologies exist and continue to be developed that are increasingly capable of manipulating telomerase activity and telomere length in human cells. It remains to be determined whether scientifically rigorous and (equally important) medically ethical approaches will emerge to directly assess the ability of telomere length modulation to correct functional disorders of human cellular function ex vivo or more challenging still, in vivo.

Constitutive and regulated expression of telomerase reverse transcriptase (hTERT) in human lymphocytes.

Human telomerase consists of two essential components, telomerase RNA template (hTER) and telomerase reverse transcriptase (hTERT), and functions to synthesize telomere repeats that serve to protect the integrity of chromosomes and to prolong the replicative life span of cells. Telomerase activity is expressed selectively in germ-line and malignant tumor cells but not in most normal human somatic cells. As a notable exception, telomerase is expressed in human lymphocytes during development, differentiation, and activation. Recent studies have suggested that regulation of telomerase is determined by transcription of hTERT but not hTER. The highly regulated expression of telomerase in lymphocytes provides an opportunity to analyze the contribution of transcriptional regulation of hTERT and hTER. We report here an analysis of hTERT expression by Northern and in situ hybridization. It was found that hTERT mRNA is expressed at detectable levels in all subsets of human lymphocytes isolated from thymus, tonsil, and peripheral blood, regardless of the status of telomerase activity. hTERT expression is regulated as a function of lineage development, differentiation, and activation. Strikingly, however, telomerase activity in these cells is not correlated strictly with the levels of hTERT and hTER transcripts. The absence of correlation between telomerase activity and hTERT mRNA could not be attributed to the presence of hTERT splice variants or to detectable inhibitors of telomerase activity. Thus, transcriptional regulation of hTERT is not sufficient to account for telomerase activity in human lymphocytes, indicating a likely role of posttranscriptional factors in the control of enzyme function.

Cutting edge: antigen-dependent regulation of telomerase activity in murine T cells.

Telomeres, structures on the ends of linear chromosomes, function to maintain chromosomal integrity. Telomere shortening occurs with cell division and provides a mechanism for limiting the replicative potential of normal human somatic cells. Telomerase, a ribonucleoprotein enzyme, synthesizes telomeric repeats on chromosomal termini, potentially extending the capacity for cell division. The present study demonstrates that resting T cells express little/no activity, and optimal Ag-specific induction of telomerase activity in vitro requires both TCR and CD28-B7 costimulatory signals. Regulation of telomerase in T cells during in vivo Ag-dependent activation was also assessed by adoptive transfer of TCR transgenic T cells and subsequent Ag challenge. Under these conditions, telomerase was induced in transgenic T cells coincident with a phase of extensive clonal expansion. These findings suggest that telomerase may represent an adoptive response that functions to preserve replicative potential in Ag-reactive lymphocytes.

Telomere lengthening and telomerase activation during human B cell differentiation.

The function of the immune system is highly dependent on cellular differentiation and clonal expansion of antigen-specific lymphocytes. However, little is known about mechanisms that may have evolved to protect replicative potential in actively dividing lymphocytes during immune differentiation and response. Here we report an analysis of telomere length and telomerase expression, factors implicated in the regulation of cellular replicative lifespan, in human B cell subsets. In contrast to previous observations, in which telomere shortening and concomitant loss of replicative potential occur in the process of somatic cell differentiation and cell division, it was found that germinal center (GC) B cells, a compartment characterized by extensive clonal expansion and selection, had significantly longer telomeric restriction fragments than those of precursor naive B cells. Furthermore, it was found that telomerase, a telomere-synthesizing enzyme, is expressed at high levels in GC B cells (at least 128-fold higher than those of naive and memory B cells), correlating with the long telomeres in this subset of B cells. Finally, both naive and memory B cells were capable of up-regulating telomerase activity in vitro in response to activation signals through the B cell antigen receptor in the presence of CD40 engagement and/or interleukin 4. These observations suggest that a novel process of telomere lengthening, possibly mediated by telomerase, functions in actively dividing GC B lymphocytes and may play a critical role in humoral immune response by maintaining the replicative potential of GC and descendant memory B cells.

Tales of tails: regulation of telomere length and telomerase activity during lymphocyte development, differentiation, activation, and aging.

Telomerase activity and the regulation of telomere length are factors which have been implicated in the control of cellular replication. These variables have been examined during human lymphocyte development, differentiation, activation, and aging. It was found that telomere length of peripheral blood CD4+ T cells decreases with age as well as with differentiation from naive to memory cells in vivo, and decreases with cell division in vitro. These results provide evidence that telomere length correlates with lymphocyte replicative history and residual replicative potential. In contrast, telomere length appears to increase during tonsil B-cell differentiation and germinal center (GC) formation in vivo. It was also found that telomerase activity is highly regulated during T-cell development and B-cell differentiation in vivo, with high levels of telomerase activity expressed in thymocytes and GC B cells, and low levels of telomerase activity in resting mature peripheral blood lymphocytes. Finally, resting lymphocytes retain the ability to upregulate telomerase activity upon activation, and this capacity does not appear to decline with age. Although the precise role of telomerase in lymphocyte function remains to be elucidated, telomerase may contribute to protection from telomere shortening in T and B lymphocytes, and may thus play a critical role in lymphocyte development, differentiation and activation. The future study of telomerase and its regulation of telomere length may enhance our understanding of how the replicative lifespan is regulated in lymphocytes.

High affinity antibodies against Lex and sialyl Lex from a phage display library.

Our previous studies of seven murine mAbs against the carbohydrate Lex Ag demonstrated that they were all encoded by VH441 and V kappa 24B. To obtain higher affinity Abs, and to ascertain whether their L chains could be encoded by other genes, we constructed a phage display library in a modified pComb 8 vector. The library contained random L chains, and Fd segments enriched in VH domains encoded by the VHX24 gene family. We selected phage with an Lex-BSA Ag, and obtained two Fab mAbs, clones 23 and 24, whose affinities were more than 100-fold higher than hybridoma mAb PM81. Both new mAbs were encoded by VH441, and their L chains were encoded by genes of the V kappa Ox1 and V kappa 9 families. In contrast to hybridoma mAb PM81, which binds only Lex, clones 23 and 24 bound sialyl Lex (SLex) as well as Lex, and clone 23 also binds the backbone carbohydrate structure nLacCer. Analysis of the binding of these three mAbs to synthetic glycolipids that contained structural modifications indicated that they recognize different aspects of the Lex structure, and suggested that they bind to limited regions of the oligosaccharide.

Regulated expression of telomerase activity in human T lymphocyte development and activation.

Telomerase, a ribonucleoprotein that is capable of synthesizing telomeric repeats, is expressed in germline and malignant cells, and is absent in most normal human somatic cells. The selective expression of telomerase has thus been proposed to be a basis for the immortality of the germline and of malignant cells. In the present study, telomerase activity was analyzed in normal human T lymphocytes. It was found that telomerase is expressed at a high level in thymocyte subpopulations, at an intermediate level in tonsil T lymphocytes, and at a low to undetectable level in peripheral blood T lymphocytes. Moreover, telomerase activity is highly inducible in peripheral T lymphocytes by activation through CD3 with or without CD28 costimulation, or by stimulation with phorbol myristate acetate (PMA)/ionomycin. The induction of telomerase by anti-CD3 plus anti-CD28 (anti-CD3/CD28) stimulation required RNA and protein synthesis, and was blocked by herbimycin A, an inhibitor of S pi protein tyrosine kinases. The immunosuppressive drug cyclosporin A selectively inhibited telomerase induction by PMA/ionomycin and by anti-CD3, but not by anti-CD3/CD28. Although telomerase activity in peripheral T lymphocytes was activation dependent and correlated with cell proliferation, it was not cell cycle phase restricted. These results indicate that the expression of telomerase in normal human T lymphocytes is both developmentally regulated and activation induced. Telomerase may thus play a permissive role in T cell development and in determining the capacity of lymphoid cells for cell division and clonal expansion.

Human naive and memory T lymphocytes differ in telomeric length and replicative potential.

The present study has assessed the replicative history and the residual replicative potential of human naive and memory T cells. Telomeres are unique terminal chromosomal structures whose length has been shown to decrease with cell division in vitro and with increased age in vivo for human somatic cells. We therefore assessed telomere length as a measure of the in vivo replicative history of naive and memory human T cells. Telomeric terminal restriction fragments were found to be 1.4 +/- 0.1 kb longer in CD4+ naive T cells than in memory cells from the same donors, a relationship that remained constant over a wide range of donor age. These findings suggest that the differentiation of memory cells from naive precursors occurs with substantial clonal expansion and that the magnitude of this expansion is, on average, similar over a wide range of age. In addition, when replicative potential was assessed in vitro, it was found that the capacity of naive cells for cell division was 128-fold greater as measured in mean population doublings than the capacity of memory cells from the same individuals. Human CD4+ naive and memory cells thus differ in in vivo replicative history, as reflected in telomeric length, and in their residual replicative capacity.

Specificity and structure of murine monoclonal antibodies against GM1 ganglioside.

Anti-GM1 antibodies have been implicated in the pathogenesis of several neurological diseases, but the role of these antibodies is still controversial. An animal model could provide insight into the mechanisms of these human disorders, but obtaining specific anti-GM1 monoclonal antibodies (mAbs) has been extremely difficult because of the weak immunogenicity of GM1 ganglioside. Four murine mAbs against GM1 were elicited by immunization of mice with lyso GM1 coupled to BSA and GM1 glycolipid. All four IgM,k mAbs bound strongly to GM1, three antibodies (125, 360 and 494) also bound very weakly to asialo GM1 (GA1) and one (156) bound weakly to GD1b. Three antibodies (125, 360 and 494) were encoded by the same VH and V kappa genes. The VH gene exhibited 97% homology to VHOX1, a member of the VHQ52N gene family, the D segment was probably derived from DQ52 and JH was identical to JH2. The V kappa gene was approximately 99% homologous to V kappa RF and J kappa was germline J kappa 2. The VH gene of mAb 156 exhibited 98% homology to VH205.12, of the VHJ558 gene family, the D segment was derived from DFL16.1, and JH was germline JH2. The V kappa and J kappa genes of mAb were identical to V kappa 8 and J kappa 1, respectively. The genes encoding these anti-GM1 antibodies were close to germline sequences and have been used to encode other antibodies. This suggests that the unresponsiveness of mice to immunization is probably due to inactivation of self-reactive B cells. These rare anti-GM1 mAbs will be valuable reagents for studies of the pathogenesis of autoimmune neuropathy in animals, and also for analyzing the tissue distribution and functions of GM1.

Structure and specificities of anti-ganglioside autoantibodies associated with motor neuropathies.

Autoantibodies that bind to GM1 ganglioside and asialo GM1 (GA1) have been implicated in the pathogenesis of motor neuropathies. To investigate the structure and specificity of these autoantibodies, peripheral blood B cells from patients with motor neuron diseases and from normal individuals were immortalized by EBV, and B cells secreting anti-GM1 or GA1 antibodies were cloned. We report an analysis of the structure and specificities of eight autoantibodies from patients with motor neuropathy, and two from normal individuals. Four antibodies were IgM, six were IgG, and all bound predominantly to GA1. The sequences of V domains of H and L chains were determined by a reverse transcription-polymerase chain reaction procedure. A variety of V genes were used to encode these antibodies: four VH1, two VH3, three VH4, one VH5, two V kappa I, two V kappa II, three V kappa III, and two V lambda II. Most V genes (13/19) exhibited less than 95% similarity to known germ-line genes, which suggests that somatic mutation was required to generate these autoantibodies, or that the relevant germ-line genes have not been identified. The average length of the H chain CDR3 was 16 amino acids, and in three antibodies this segment contained more than 20 amino acids. It was not possible to identify amino acid sequences that were encoded by germ-line D segments by conventional alignment of sequences. Partial analogies could be identified by introducing gaps, allowing mismatches and searching for D-D fusions and inversions. These results indicate that anti-GA1 antibodies can be encoded by a variety of VH-VL pairs, that the antibodies exhibit extensive somatic mutation, and that the CDR3 segments are generated by a number of nonconventional mechanisms.

Polymorphism of human immunoglobulin VH4 germ-line genes.

The human immunoglobulin VH4 gene family is thought to contain approximately 10 germ-line genes and to exhibit little polymorphism. We report here an analysis of VH4 germ-line genes that were amplified from DNA of two unrelated individuals. Ten unique (non-repetitive) sequences were obtained from individual A and 11 from individual B. Nine of these sequences represent new germ-line genes, and 8/9 exhibit only 89%-96% similarity to genes identified previously. Subsets of VH4 genes displayed distinctive nucleotide motifs that account for most of the differences between them. This observation suggests that diversity in the VH4 gene family arose from the acquisition of blocks of nucleotides, rather than by accumulation of point mutations. These nucleotide blocks could have been acquired by gene conversion or by homologous recombination. All of the VH4 genes have a potential N-linked glycosylation site at Asn 60, and some genes encode a second site at Asn 52. The VH4 gene family is larger and more polymorphic than appreciated previously. Immunoglobulin gene polymorphism may make a significant contribution to hereditary variations in the immune response and to the genetic predisposition to autoimmune diseases.