Design considerations for array CGH to oligonucleotide arrays.

BACKGROUND: Representational oligonucleotide microarray analysis has been developed for detection of single nucleotide polymorphisms and/or for genome copy number changes. In this process, the intensity of hybridization to oligonucleotides arrays is increased by hybridizing a polymerase chain reaction (PCR)-amplified representation of reduced genomic complexity. However, hybridization to some oligonucleotides is not sufficiently high to allow precise analysis of that portion of the genome. METHODS: In an effort to identify aspects of oligonucleotide hybridization affecting signal intensity, we explored the importance of the PCR product strand to which each oligonucleotide is homologous and the sequence of the array oligonucleotides. We accomplished this by hybridizing multiple PCR-amplified products to oligonucleotide arrays carrying two sense and two antisense 50-mer oligonucleotides for each PCR amplicon. RESULTS: In some cases, hybridization intensity depended more strongly on the PCR amplicon strand (i.e., sense vs. antisense) than on the detection oligonucleotide sequence. In other cases, the oligonucleotide sequence seemed to dominate. CONCLUSION: Oligonucleotide arrays for analysis of DNA copy number or for single nucleotide polymorphism content should be designed to carry probes to sense and antisense strands of each PCR amplicon to ensure sufficient hybridization and signal intensity.

The immune system and gene expression microarrays--new answers to old questions.

The recent increase in availability of gene expression technologies has the potential to dramatically expand our understanding of cellular immunology in molecular detail. Expression levels of tens of thousands of genes can be measured in dozens of samples in only a few days, and this data can be integrated with sequence informatics to tentatively assign some (limited) functional information to a majority of these genes. In this review we discuss some initial applications of these new tools to the fields of lymphocyte and monocyte differentiation pathways, the tolerance or immunity decision process, and B cell transformation. These examples illustrate the power of unbiased, 'wide-net', approaches both to drive immunological research in previously unexpected directions and to confirm classic tenets of immunology.

B-lymphocyte quiescence, tolerance and activation as viewed by global gene expression profiling on microarrays.

Self-tolerance is achieved by deleting or regulating self-reactive lymphocytes at a series of cellular checkpoints placed at many points along the developmental pathways to plasma cells and effector T cells. At each checkpoint, what are the molecular pathways that determine whether a lymphocyte remains quiescent, begins dividing, differentiates or dies? In splenic B cells, the decision between quiescence, tolerance by anergy, and activation provides a tractable setting to explore these issues by global gene expression profiling on DNA microarrays. Here we discuss the application of microarrays to illuminate a set of cell fate decisions that appear to be determined by summation of numerous small changes in expression of stimulatory and inhibitory genes. Many genes with known or predicted inhibitory functions are highly expressed in naive, quiescent B cells, notably the signal inhibitor SLAP and DNA-binding proteins of the Kruppel family (LKLF, BKLF, GKLF), Tsc-22, GILZ, Id-3, and GADD45. Activation of naive B cells, triggered by acute binding of antigen to the B-cell receptor, involves a rapid decrease in expression of these inhibitory genes. Promitotic genes are induced in parallel, including c myc, LSIRF/IRF4, cyclin D2, Egr-1 and Egr-2, as are the anti-apoptotic gene A1 and genes for the T-cell-attracting chemokines MIP-1alpha and beta. B-cell tolerance through the process of anergy, induced by chronic binding of self antigen, maintains expression of the inhibitory genes found in quiescent B cells and induces an additional set of inhibitory genes. The latter include inhibitors of signaling - CD72, neurogranin, pcp4 - and additional inhibitors of gene expression such as SATB1, MEF2C, TGIF and Nab-2. The effects of tolerance, the immunosuppressive drug FK506 and other modulators of calcium or MAPK signaling allow individual gene responses to be linked to different signal transduction pathways. The global molecular profiles obtained illustrate how quiescence and anergy are actively maintained in circulating B cells, how these states are switched to clonal expansion and how they could be better emulated by pro-tolerogenic drugs.

Genomic-scale gene expression analysis of lymphocyte growth, tolerance and malignancy.

Immunologists are already comfortable with the need for monitoring many different gene products simultaneously. It is a common challenge to remember what CD-one-hundred-and-something is, and an ever-increasing number of colours are required for identification on the flow cytometer. Gene expression arrays now offer the possibility of extending this approach beyond the cell surface and expanding it dramatically to survey the entire catalogue of gene transcripts in a lymphoid cell.

How self-tolerance and the immunosuppressive drug FK506 prevent B-cell mitogenesis.

Therapy for transplant rejection, autoimmune disease and allergy must target mature lymphocytes that have escaped censoring during their development. FK506 and cyclosporin are immunosuppressants which block three antigen-receptor signalling pathways (NFAT, NFkappaB and JNK), through inhibition of calcineurin, and inhibit mature lymphocyte proliferation to antigen. Neither drug induces long-lived tolerance in vivo, however, necessitating chronic use with adverse side effects. Physiological mechanisms of peripheral tolerance to self-antigens provide an opportunity to emulate these processes pharmacologically. Here we use gene-expression arrays to provide a molecular explanation for the loss of mitogenic response in peripheral B-cell anergy, one aspect of immunological tolerance. Self-antigen induces a set of genes that includes negative regulators of signalling and transcription but not genes that promote proliferation. FK506 interferes with calcium-dependent components of the tolerance response and blocks an unexpectedly small fraction of the activation response. Many genes that were not previously connected to self-tolerance are revealed, and our findings provide a molecular fingerprint for the development of improved immunosuppressants that prevent lymphocyte activation without blocking peripheral tolerance.

Evolutionary dynamics of non-coding sequences within the class II region of the human MHC.

About 40% (350 kb) of the human MHC class II region has been sequenced and a coordinated effort to sequence the entire MHC is underway. In addition to the coding information (22 genes/pseudogenes), the non-coding sequences reveal novel information on the organisation and evolution of the MHC as demonstrated here by the example of a 200 kb contig that has been analysed for local and global features. In conjunction with cross-species comparisons, our results present new evidence on the structure of isochores, the evolutionary dynamics of repeat-mediated recombination and its effect on certain MHC encoded genes, and a higher than average degree of natural polymorphism that has implications for sequencing the human genome. We also report the finding of a class I-related pseudogene (HLA-ZI) in the middle of the class II region, which provides the first direct evidence for DNA exchange between these two related regions in man.

DNA sequencing of the MHC class II region and the chromosome 6 sequencing effort at the Sanger Centre.

The human Major Histocompatibility Complex (MHC) is located on the short arm of chromosome 6 (6p21.3) and spans about 4 Mb. According to different gene families the MHC is subdivided into a class I, class II and class III region and many of its gene products are associated with the immune system and the susceptibility to various diseases. To date, we have sequenced about 40% (400 kb) of the class II region between HLA-DP and HLA-DQ and a coordinated effort to sequence the entire MHC is well underway. Analysis of the sequence revealed several novel genes and provides new insights into the molecular organisation and evolution of the MHC. All our data are publicly available via the MHC database (MHCDB) which allows rapid access, retrieval and display in the context of other MHC associated data. MHCDB is online available at (http:(/)/www.hgmp.mrc.ac.uk/) and, together with all our sequences also via anonymous ftp (ftp.icnet.uk/icrf-public).

Proteasome components with reciprocal expression to that of the MHC-encoded LMP proteins.

BACKGROUND: Intracellular proteins are processed into small peptides that bind HLA class I molecules of the major histocompatibility complex (MHC) in order to be presented to T lymphocytes. The proteasome, a multi-subunit protease, has recently been implicated in the generation of these peptides. Two genes encoding proteasome subunits, LMP2 and LMP7, are tightly linked to the TAP peptide transport loci in the class II region of the human MHC. Inclusion of the LMP subunits may alter proteasome activity, biasing it towards the production of peptides with carboxyl termini appropriate for binding HLA class I molecules. Nevertheless, mutant cells that lack the LMP genes are able to process and present antigens at the cell surface at similar levels to wild-type cells. These results raise questions about the role of the proteasome, and in particular of the LMP subunits, in antigen processing. RESULTS: We have cloned the genes encoding a new proteasome subunit, MB1, which is closely related to LMP7, and that encoding a second subunit, Delta, which is closely related to LMP2. Expression of the MB1 and delta genes is reciprocal to that of the LMP genes: MB1 and delta are up-regulated in mutant cell lines lacking LMPs and down-regulated in the presence of gamma-interferon. The MB1 and delta genes are found to be located on chromosomes 14 and 17, respectively, raising interesting evolutionary questions about how the LMP genes independently became incorporated into the MHC. CONCLUSIONS: We suggest that the subtle phenotype of LMP-deficient cell lines results from the compensatory expression in these lines of two other proteasome subunits, MB1 and Delta.

The major histocompatibility complex-encoded proteasome component LMP7: alternative first exons and post-translational processing.

The LMP7 gene maps to the major histocompatibility complex class II region. The derived protein sequence shares homology with N-terminal amino acid sequence from proteasome subunits (Glynne, R., Powis, S. H., Beck, S., Kelly, A., Kerr, L.-A. and Trowsdale, J., Nature 1991. 353: 357) and it has been suggested that LMP7 is involved in the degradation of endogenous antigens prior to their presentation through class I (Robertson, M., Nature 1991. 353: 300). We have isolated a second LMP7 transcript which has a different first exon to the published sequence. Both transcripts were expressed in cell lines from a number of tissues and both responded to interferon-gamma. An anti-LMP7 antiserum precipitated proteins similar in their migration on sodium dodecyl sulfate-polyacrylamide gel electrophoresis to those precipitated by an anti-proteasome serum. Western blot analysis of anti-proteasome precipitates demonstrated that the LMP7 protein is incorporated into the proteasome but has a molecular mass of 23 kDa, 7 kDa smaller than expected fro the derived protein sequence of either of the cDNA. A pulse-chase experiment indicated that post-translational cleavage of the LMP7 N terminus precedes the formation of the 23-kDa proteasome subunit. To our knowledge, LMP7 provides the first biochemical evidence for such processing of proteasome components.

Polymorphism in a second ABC transporter gene located within the class II region of the human major histocompatibility complex.

Recent studies have identified genes within the major histocompatibility complex (MHC) that may play a role in presentation of antigenic peptides to T cells. We have previously described RING4, a gene within the human MHC class II region that has sequence homology with members of the ABC ("ATP-binding cassette") transporter superfamily. We now report the nucleotide sequence of RING11, a second ABC transporter gene located approximately 7 kilobases telomeric to RING4, RING11 is gamma-interferon inducible, a property shared with other genes involved in antigen presentation. Comparison between the amino acid sequences of RING11 and RING4 reveals strong homology. We propose that they form a heterodimer that transports peptides from the cytoplasm into the endoplasmic reticulum. We have identified two RING11 alleles, which differ in the length of their derived protein sequence by 17 amino acids. The more common of these alleles is present in a Caucasoid population at a frequency of 79%.

Second proteasome-related gene in the human MHC class II region.

Antgen processing involves the generation of peptides from cytosolic proteins and their transport into the endoplasmic reticulum where they associate with major histocompatibility complex (MHC) class I molecules. Two genes have been identified in the MHC class II region, RING4 and RING11 in humans, which are believed to encode the peptide transport proteins. Attention is now focused on how the transporters are provided with peptides. The proteasome, a large complex of subunits with multiple proteolytic activities, is a candidate for this function. Recently we reported a proteasome-related sequence, RING10, mapping between the transporter genes. Here we describe a second human proteasome-like gene, RING12, immediately centromeric of the RING4 locus. Therefore RING12, 4, 10 and 11 form a tightly linked cluster of interferon-inducible genes within the MHC with an essential role in antigen processing.

A proteasome-related gene between the two ABC transporter loci in the class II region of the human MHC.

It is now possible to paint a detailed picture of how cytoplasmic proteins are handled by the immune system. They are apparently degraded in the cytoplasm into peptides. These are then transported into the endoplasmic reticulum where they encounter class I major histocompatibility complex (MHC) molecules. Once loaded with peptide, the HLA molecules move through the Golgi apparatus to the cell membrane. Until recently, it had not been established how peptides without signal sequences cross the ER membrane. However, a number of papers have now described a pair of membrane transporter genes of the ABC (ATP-binding cassette) super-family which are attractive candidates for this function. Both transporter genes, which may encode two halves of a heterodimer, are situated in the class II region of the MHC. There is evidence that other putative components of the processing machinery, the LMPs (low molecular mass polypeptides), are also encoded in the MHC. Similarities between the properties of the LMPs and a large intracellular protease complex, called proteasome, have led to the suggestion that LMPs are involved in processing antigens. We have now identified a human gene with sequence homology to proteasome components. Remarkably, this gene maps between the two putative peptide transporter genes.