Functional redundancy between Apc and Apc2 regulates tissue homeostasis and prevents tumorigenesis in murine mammary epithelium.

Aberrant Wnt signaling within breast cancer is associated with poor prognosis, but regulation of this pathway in breast tissue remains poorly understood and the consequences of immediate or long-term dysregulation remain elusive. The exact contribution of the Wnt-regulating proteins adenomatous polyposis coli (APC) and APC2 in the pathogenesis of human breast cancer are ill-defined, but our analysis of publically available array data sets indicates that tumors with concomitant low expression of both proteins occurs more frequently in the 'triple negative' phenotype, which is a subtype of breast cancer with particularly poor prognosis. We have used mouse transgenics to delete Apc and/or Apc2 from mouse mammary epithelium to elucidate the significance of these proteins in mammary homeostasis and delineate their influences on Wnt signaling and tumorigenesis. Loss of either protein alone failed to affect Wnt signaling levels or tissue homeostasis. Strikingly, concomitant loss led to local disruption of ß-catenin status, disruption in epithelial integrity, cohesion and polarity, increased cell division and a distinctive form of ductal hyperplasia with 'squamoid' ghost cell nodules in young animals. Upon aging, the development of Wnt activated mammary carcinomas with squamous differentiation was accompanied by a significantly reduced survival. This novel Wnt-driven mammary tumor model highlights the importance of functional redundancies existing between the Apc proteins both in normal homeostasis and in tumorigenesis.

Very long-term self-renewal of small intestine, colon, and hair follicles from cycling Lgr5+ve stem cells.

The intestinal epithelium and the hair follicle represent examples of rapidly self-renewing tissue in adult mammals. We have recently identified a novel stem cell gene Lgr5 expressed in multiple adult tissues. At the bottoms of crypts in small intestine and colon as well as in hair follicles, Lgr5 marks cycling cells with stem cell properties (Barker et al. 2007; Jaks et al. 2008). Using an inducible Lgr5-Cre knockin allele in conjunction with the Rosa26-LacZ Cre reporter strain, long-term lineage-tracing experiments were performed in adult mice. The Lgr5(+ve) crypt-based cell generated all epithelial lineages during a 14-month period, implying that it represents the stem cell of the small intestine and colon. Similarly, lineage tracing during a 14-month period revealed that Lgr5(+ve) cells located in the bulge of the hair follicle sustained multiple rounds of hair growth. These observations support the counterintuitive notion that Lgr5(+ve) cells are actively cycling, yet represent long-term stem cells of these adult, self-renewing tissues.

Mutations in the APC tumour suppressor gene cause chromosomal instability.

Two forms of genetic instability have been described in colorectal cancer: microsatellite instability and chromosomal instability. Microsatellite instability results from mutations in mismatch repair genes; chromosomal instability is the hallmark of many colorectal cancers, although it is not completely understood at the molecular level. As truncations of the Adenomatous Polyposis Coli (APC) gene are found in most colorectal tumours, we thought that mutations in APC might be responsible for chromosomal instability. To test this hypothesis, we examined mouse embryonic stem (ES) cells homozygous for Min (multiple intestinal neoplasia) or Apc1638T alleles. Here we show that Apc mutant ES cells display extensive chromosome and spindle aberrations, providing genetic evidence for a role of APC in chromosome segregation. Consistent with this, APC accumulates at the kinetochore during mitosis. Apc mutant cells form mitotic spindles with an abundance of microtubules that inefficiently connect with kinetochores. This phenotype is recapitulated by the induced expression of a 253-amino-acid carboxy-terminal fragment of APC in microsatellite unstable colorectal cancer cells. We conclude that loss of APC sequences that lie C-terminal to the beta-catenin regulatory domain contributes to chromosomal instability in colorectal cancer.

The many faces of the tumor suppressor gene APC.

Inactivation of the tumor suppressor adenomatous polyposis coli (APC) protein is a critical early step in the development of familial and sporadic colon cancer. Close examination of the function of APC has shown that it is a multifunctional protein involved in a wide variety of processes, including regulation of cell proliferation, cell migration, cell adhesion, cytoskeletal reorganization, and chromosomal stability. Tantalizing clues to the different functions of APC have been provided by the identification of proteins interacting with several discrete motifs within APC. Each of these putative functions could link APC inactivation with tumorigenesis. Here, we will summarize recent findings regarding the diverse role of APC. We will emphasize the interaction of APC with different binding partners, the role of these complex interactions for normal functioning of the cell, and how disruption of these interactions may play a role in tumor development. The rapid progress made recently shows the many faces of APC, leading to a constant reappreciation of this multitasking tumor suppressor protein.

Identification of APC2, a homologue of the adenomatous polyposis coli tumour suppressor.

The adenomatous polyposis coli (APC) tumour-suppressor protein controls the Wnt signalling pathway by forming a complex with glycogen synthase kinase 3beta (GSK-3beta), axin/conductin and betacatenin. Complex formation induces the rapid degradation of betacatenin. In colon carcinoma cells, loss of APC leads to the accumulation of betacatenin in the nucleus, where it binds to and activates the Tcf-4 transcription factor (reviewed in [1] [2]). Here, we report the identification and genomic structure of APC homologues. Mammalian APC2, which closely resembles APC in overall domain structure, was functionally analyzed and shown to contain two SAMP domains, both of which are required for binding to conductin. Like APC, APC2 regulates the formation of active betacatenin-Tcf complexes, as demonstrated using transient transcriptional activation assays in APC -/- colon carcinoma cells. Human APC2 maps to chromosome 19p13.3. APC and APC2 may therefore have comparable functions in development and cancer.

VH4.21-encoded natural autoantibodies with anti-i specificity mirror those associated with cold hemagglutinin disease.

The Ig VH regions of virtually all human pathogenic cold agglutinin (CA) anti-i/l autoantibodies are encoded by a single Ig VH gene segment, VH4.21, in conjunction with a highly variable CDR3 structure. The anti-I specificity is often associated with V kappa III-encoded L chains, whereas anti-i autoantibodies appear to use a broader array of kappa and lambda VL gene segments. B cells expressing VH4.21 are abundantly present in adult lymphoid tissues from healthy individuals but their relationship with B cells secreting pathogenic CA is unknown. Herein we have analyzed the distribution of VH4.21-expressing B cells in fetal, neonatal, and adult B cell populations using the monoclonal anti-VH4.21 antibody 9G4. In addition, we have analyzed the anti-i and anti-I binding capacity and V regions of 19 VH4.21-encoded mAb secreted by cord and adult blood-derived cell lines from healthy individuals. The results show that VH4.21 expressing B cells are overrepresented in all repertoires studied and are evenly distributed over cord blood CD5+ and CD5- B cell populations. VH4.21-encoded H chains strongly predispose for anti-i binding capacity, regardless of the VL regions or H chain CDR3 structure. The avidity of some of these antibodies was similar to those of pathogenic CA. In addition, we found evidence for monospecific anti-I binding in antibodies encoded by other members of the VH4 gene family. We conclude that VH4.21-encoded antibodies with anti-i specificity from the normal B cell repertoire mirror their pathogenic counterparts and that naturally occurring anti-I antibodies may be encoded by a more diverse array of VH4 genes.

Expression pattern of the most JH-proximal human VH gene segment (VH6) in the B cell and antibody repertoire suggests a role of VH6-encoded IgM antibodies in early ontogeny.

We have developed a mAb (JE-6) that recognizes an Id encoded by the most JH-proximal human VH gene segment (VH6) in or near germ-line configuration. This mAb was used to determine the frequency of Id JE6+ B cells in large collections of monoclonal EBV-transformed and short term B cell lines derived from fetal, neonatal, and adult lymphoid tissues. Moreover, we investigated the presence of Id JE-6+ Ig in sera from neonates and adults and determined the (auto)antigen binding properties of VH6-encoded IgM mAb. We detected a fivefold overrepresentation of VH6-expressing IgM producing B cells in fetal tissues, cord blood, and adult bone marrow relative to adult blood. In cord blood, but not in adult blood sera, germ-line VH6-encoded IgM molecules were readily detectable. IgM secreted by VH6-expressing B cell clones displayed highly conserved and virtually identical autoantigen binding properties, independent of the length and composition of the IgH chain CDR3 region and L chain isotype. Collectively, these results suggest that the VH6 gene and the antibodies it encodes play an important role in early human ontogeny.

High frequency of somatically mutated IgM molecules in the human adult blood B cell repertoire.

Nucleotide sequence analysis of cDNA encoded by the single member of the human immunoglobulin VH6 gene family show that blood B cells in adults, but not in neonates, frequently express somatically mutated IgM molecules. The number of mutations in VH6-encoded cDNA from adult blood ranged from 2 to 19 mutations/VH gene (average 10.1/VH gene). The distribution of silent and replacement mutations suggests that at least some of the VH6 genes were derived from B cells that were activated and selected by antigen. We conclude that the blood B cell repertoire in adult humans, in contrast to its much-studied murine splenic counterpart, is a rich source of highly mutated IgM molecules.

A human systemic lupus erythematosus-related anti-cardiolipin/single-stranded DNA autoantibody is encoded by a somatically mutated variant of the developmentally restricted 51P1 VH gene.

We report the Ig H and L chain V region sequences from the cDNAs encoding a monoclonal human IgG anti-cardiolipin/ssDNA autoantibody (R149) derived from a patient with active SLE. Comparison with the germ-line V-gene repertoire of this patient revealed that R149 likely arose as a consequence of an Ag-driven selection process. The Ag-binding portions of the V regions were characterized by a high number of arginine residues, a property that has been associated with anti-dsDNA autoantibodies from lupus-prone mice and patients with SLE. The VH gene encoding autoantibody R149 was a somatically mutated variant of the 51P1 gene segment, which is frequently associated with the restricted fetal B cell repertoire, malignant CD5 B cells, and natural autoantibodies. These data suggest that in SLE patients a common antigenic stimulus may evoke anti-DNA and anti-cardiolipin autoantibodies and provide further evidence that a small set of developmentally restricted VH genes can give rise to disease-associated autoantibodies through Ag-selected somatic mutations.

Molecular approaches to the study of human B-cell and (auto)antibody repertoire generation and selection.

We have shown that the restricted repertoire of VH genes expressed in second trimester human fetal liver is not solely determined by JH proximity. Furthermore, by following the fate of two VH gene segments in different B-cell repertoires, we have provided evidence that multiple factors contribute to the frequency with which individual VH genes are utilized. We found that the repertoire of adult blood IgM-bearing B cells contains a high proportion of B lymphocytes that express extensively mutated VH genes. Finally, we show that somatically-mutated variants of particular VH and VL genes that, in germline configuration, are frequently found in the early B-cell repertoire and in natural autoantibodies, encode pathogenic IgG autoantibodies characteristic of human SLE. These VH and VL genes harbor all the characteristics of an antigen-driven B-cell activation and selection process.

Sequence analysis of members of the human Ig VH4 gene family derived from a single VH locus. Identification of novel germ-line members.

We have generated a mouse x human heterohybridoma that contains a single copy of chromosome 14 and, thus, a haploid set of Ig VH genes. This cell line was used to investigate the germ-line content and nucleotide sequences of members of the VH4 gene family in a polymerase chain reaction-based approach. The analysis of 58 full-length sequences revealed the presence of 12 different germ-line VH4 genes, each of which is potentially functional. These germ-line VH4 genes were compared with the nucleotide sequences of published VH4 genes. Three VH4 genes were 100% identical to previously published sequences and belong to a group of VH4 genes that are strongly conserved and highly prevalent in the human population. Three VH4 genes in our collection displayed greater than 99.3% sequence identity with reported germ-line VH4 sequences and likely represent allelic counterparts of these genes. Six genes displayed less than 97.2% sequence identity with published VH4 genes and were identified as novel members of the human VH4 gene family or more distantly related alleles of known VH4 genes. Collectively, these data suggest that, overall, the human VH4 gene family may be more diverse than hitherto assumed, whereas a number of individual members are nonpolymorphic and extremely well conserved.

Induction and characterization of monoclonal anti-idiotypic antibodies reactive with idiotopes of canine parvovirus neutralizing monoclonal antibodies.

Monoclonal anti-idiotypic (anti-Id) antibodies (Ab2) were generated against idiotypes (Id) of canine parvovirus (CPV) specific monoclonal antibodies (MoAbs). The binding of most of these anti-Id antibodies to their corresponding Id could be inhibited by antigen, thus classifying these anti-Id antibodies as Ab2 gamma or Ab2 beta. By inhibiting experiments it was shown that these anti-Id antibodies did not recognize interspecies cross-reactive idiotopes, but recognized private idiotopes, uniquely associated with the Id of the anti-CPV MoAb used for immunization. This classifies these anti-Id antibodies as non-internal image Ab2 gamma. The potential use of these non-internal image anti-Id antibodies for the induction of antiviral antibodies in the CPV system is discussed.

Somatic mutations in the variable regions of a human IgG anti-double-stranded DNA autoantibody suggest a role for antigen in the induction of systemic lupus erythematosus.

The processes that govern the generation of pathogenic anti-DNA autoantibodies in human systemic lupus erythematosus (SLE) are largely unknown. Autoantibodies may arise as a consequence of polyclonal B cell activation and/or antigen-driven B cell activation and selection. The role of these processes in humoral autoimmunity may be studied by molecular genetic analysis of immunoglobulin (Ig) variable (V) regions of antibodies that are characteristic of SLE. We have analyzed the gene elements that encode a high affinity, IgG anti-double-stranded DNA autoantibody secreted by a monoclonal Epstein-Barr virus (EBV)-transformed cell line derived from a patient with active SLE. In addition, we have identified, cloned, and sequenced the germline counterparts of the VH and VL genes expressed in this autoantibody. The comparison of both sets of gene elements shows that the autoantibody VH and VL regions harbor numerous somatic mutations characteristic of an antigen-driven immune response. The light chain expressed in this autoantibody is a somatically mutated variant of the kv325 germline gene that is frequently associated with paraproteins having autoantibody activity and with Ig molecules produced by malignant B cells that express the CD5 antigen. Furthermore, the utilized DH segment has been repeatedly found in multireactive, low affinity IgM anti-DNA autoantibodies from SLE patients and healthy individuals. These results suggest that pathogenic IgG anti-DNA autoantibodies in human SLE may arise through antigen-driven selection of somatic mutations in the gene elements that frequently encode multireactive IgM autoantibodies.

Autoantibodies encoded by the most Jh-proximal human immunoglobulin heavy chain variable region gene.

Little is known about the utilization of human Ig heavy chain variable gene segments (VH segments) in different B-lineage cell populations or in antibodies of particular specificity and function. We now demonstrate that human antibodies with Ig VH regions encoded by the most JH-proximal human VH segment (VH6) have specificities resembling those of autoantibodies present in sera of patients with systemic lupus erythematosus (e.g., anti-DNA and anticardiolipin). These specificities appear to be encoded by the germline VH6 gene because the activity was found in multiple independent VH6 antibodies in which the light chain varied with respect to isotype and V kappa subgroup. Features of CDR3 length and somatic mutation patterns in several VH6 antibodies suggested that they were selected by the immune system.