Although the Xenopus immunoglobulin heavy chain locus is structurally and functionally similar to mammalian IgH loci, Xenopus antibodies are limited in heterogeneity, and they mature only slightly in affinity during immune responses. During the antibody response of isogenic frogs to DNP-KLH, it and v cDNA sequences using elements of the VH1 family were cloned, sequenced and compared with germline counterparts. There were zero to four mutations per sequence, mostly single base substitutions, in the framework and CDRs 1 and 2 of VH. No mutations were found in JH. Since the point mutation rate was only 4-to 7-fold lower than that calculated for mice, affinity maturation does not seem to be limited by mutant availability. Because of a relatively low ratio of replacement to silent mutations in the CDRs and a very high ratio of GC to AT base pairs altered by mutation, it is suggested that the problem results from the absence of an effective mechanism for selecting mutants, which in turn might be related to the absence of germinal centers in Xenopus.
The formation of the neuromuscular junction (NMJ) is directed by reciprocal interactions between motor neurons and muscle fibers. Neuregulin (NRG) and Agrin from motor nerve terminals are both implicated. Here, we demonstrate that NMJs can form in the absence of the NRG receptors ErbB2 and ErbB4 in mouse muscle. Postsynaptic differentiation is, however, induced by Agrin. We therefore conclude that NRG signaling to muscle is not required for NMJ formation. The effects of NRG signaling to muscle may be mediated indirectly through Schwann cells.
Since the larval and adult antibody responses are distinct and restricted in the clawed toad Xenopus, it offers a near ideal model for studying the ontogeny of antibody repertoires and the mechanisms involved. Immunoglobulin heavy chain (IgH) cDNA clones and B cell IgH DNA clones from various larval and adult libraries have been analysed in isogenic Xenopus. Some features are similar in adults and tadpoles, while others differ and explain the particularities observed previously at the protein level. Among the similarities we found are: (i) the mode of rearrangements (there are approximately 50% abortive events in B cells from both stages), (ii) VH family usage (10 of 11 known VH families are expressed proportionally to the number of VH elements per family), and (iii) JH usage (of the eight to nine Xenopus JH elements, two are used in approximately 70% of the VH regions in both stages of development). We found that there is relatively higher membrane exon expression in tadpoles compared with adults; and that most of the differences come from the diversification of CDR3 through DH usage and N diversification. Unlike in mammals, Xenopus DH elements are used with a remarkable flexibility with inversion, fusions and usage in different reading frames, but tadpoles show a strong bias for the usage of only a few DH elements and of a preferred reading frame. There is N diversification, which further increases CDR3 heterogeneity, in adult Xenopus but virtually none in tadpoles. These observations can account for the fact that larval antibody responses are less heterogeneous than those of adults.
Immunoglobulin (Ig) heavy chain class switch recombination has been studied at the DNA level in a non-mammalian vertebrate, the amphibian Xenopus. A switch (S) region of about 5 kb has been identified in the JH-C mu intron of the Ig heavy chain locus in Xenopus. S mu contains 23 repeats approximately 150 bp long. Each repeat consists of internal shorter repeats and palindromic sequences, such as AGCT, which they share with mammalian switch regions. A deletion of the mu gene and the joining of the S regions of mu and chi occurs in B cells expressing IgX, one of the two non-mu isotypes in Xenopus. S chi shows no sequence homology with S mu and is characterized by 16 and 121 bp repeats and a high frequency of CATG, AGCA and TGCA palindromes. Both IgM and IgX S regions are AT rich and not GC rich like mammalian S regions. Recombination occurs, most of the time, at positions (microsites) where a single-stranded DNA folding program predicts the transition from a stem to a loop structure. This feature is conserved in most mammalian switch junctions which points to the general existence and involvement of microsites at one step of the determination of the recombination break-point. The recombinogenic nature of the switch regions is therefore linked to its structure rather than to its base composition, the repetitive occurrence of palindromes being essential at creating many microsites.
CTX, a cortical thymocyte marker in Xenopus, is an immunoglobulin superfamily (Igsf) member comprising one variable and one constant C2-type Igsf domain, a transmembrane segment and a cytoplasmic tail. Although resembling that of the TCR and immunoglobulins, the variable domain is not encoded by somatic rearrangement of the gene but by splicing of two half-domain exons. The C2 domain, also encoded by two exons, has an extra pair of cysteines. The transmembrane segment is free of charged residues, and the cytoplasmic tail (70 amino acids) contains one tyrosine and many glutamic acid residues. ChT1, a chicken homologue of CTX, has the same structural and genetic features, and both molecules are expressed on the thymocyte surface. We cloned new mouse (CTM) and human (CTH) cDNA and genes which are highly homologous to CTX/ChT1 but not lymphocyte specific. Similarity with recently described human cell surface molecules, A33 antigen and CAR (coxsackie and adenovirus 5 receptor), and a number of expressed sequence tags leads us to propose that CTX defines a novel subset of the Igsf, conserved throughout vertebrates and extending beyond the immune system. Strong homologies within vertebrate sequences suggest that the V and C2 CTX domains are scions of a very ancient lineage.
The Xenopus IgH locus includes various variable (VH) families, several putative diversity (DH) and at least seven joining (JH) elements, but-although structurally very similar to the mammalian locus-it contributes to a restricted antibody repertoire. The largest three VH families contain 15 -30 VH elements which are interspersed at the VHI -VHII and VHII -VHIII boundaries. Twenty-nine genomic and eight expressed VH regions have been sequenced. Each VH family has distinct promoter elements with up to three octamers (ATGCAAAT) in either orientation. The incidence of pseudogenes ranges from <15% in VHI and VHII to -50% in VHIII, consistent with their relative expression. CDR1 and CDR2 show low overall diversity with nucleotide divergence limited to parts of the CDRs.Randomly selectedly VH elements share CDR1 and CDR2, in some cases also with expressed VH regions.Thus, the complexity of VH elements is not maximal.Patterns of sequence similarities or identities indicate recombination or gene conversion events; sets of direct and inverted repeats flank the sites of, or lie within FR or CDR sequences where these genetic events may occur. Restricted antibody diversity in Xenopus seems therefore to be at least partially related to low complexity of VH elements, frequence of pseudogenes and expression regulated by specific promoter elements; diversity may potentially be increased by (non)homologous recombination events.
The amphibian Xenopus and mammals have similar organization and usage of their immunoglobulin gene loci with combinatorial joining of V, D and J elements. The differences in B-cell development between mammals and this amphibian are due to major differences in developmental kinetics, cell number and lymphoid organ architecture. Unlike mammals, the immune system of Xenopus develops early under pressure to develop quickly and to produce a heterogeneous repertoire before lymphocyte numbers reach 5,000, thereby imposing a limitation on clonal amplification. In addition, it is submitted to metamorphosis. Thus, during the early antigen-independent period, several features of B-cell development related to immune diversification are under strict genetically preprogramed control: 1) D reading frames contribute complementary determining region 3 with features that occur in mammals by somatic selection, 2) the temporal stepwise utilization of V(H) genes in Xenopus occur in families probably because of structural DNA features rather than their position in the locus. Larval and adult immune responses differ in heterogeneity. Larval rearrangements lack N diversity. During the course of immune responses, somatic mutants are generated at the same rate as in other vertebrates but are not optimally selected, probably due to the simpler organization of the lymphoid organs, with neither lymph nodes nor germinal centers resulting in poor affinity maturation. Switch from IgM to other isotypes is mediated by loop-excision deletion of the IgM constant region gene via switch regions which, unlike their mammalian counterpart, are A-T rich and reveal conserved microsites for the breakpoints.
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