Gérard Dumas

Distinct regulatory cascades govern extraocular and pharyngeal arch muscle progenitor cell fates.

Genetic regulatory networks governing skeletal myogenesis in the body are well understood, yet their hierarchical relationships in the head remain unresolved. We show that either Myf5 or Mrf4 is necessary for initiating extraocular myogenesis. Whereas Mrf4 is dispensable for pharyngeal muscle progenitor fate, Tbx1 and Myf5 act synergistically for governing myogenesis in this location. As in the body, Myod acts epistatically to the initiating cascades in the head. Thus, complementary pathways, governed by Pax3 for body, and Tbx1 for pharyngeal muscles, but absent for extraocular muscles, activate the core myogenic network. These diverse muscle progenitors maintain their respective embryonic regulatory signatures in the adult. However, these signatures are not sufficient to ensure the specific muscle phenotypes, since the expected differentiated phenotype is not manifested when satellite cells are engrafted heterotopically. These findings identify novel genetic networks that may provide insights into myopathies which often affect only subsets of muscles.

Developing Bones are Differentially Affected by Compromised Skeletal Muscle Formation

Mechanical forces are essential for normal adult bone function and repair, but the impact of prenatal muscle contractions on bone development remains to be explored in depth in mammalian model systems. In this study, we analyze skeletogenesis in two ‘muscleless’ mouse mutant models in which the formation of skeletal muscle development is disrupted; Myf5nlacZ/nlacZ:MyoD−/− and Pax3Sp/Sp (Splotch). Ossification centers were found to be differentially affected in the muscleless limbs, with significant decreases in bone formation in the scapula, humerus, ulna and femur, but not in the tibia. In the scapula and humerus, the morphologies of ossification centers were abnormal in muscleless limbs. Histology of the humerus revealed a decreased extent of the hypertrophic zone in mutant limbs but no change in the shape of this region. The elbow joint was also found to be clearly affected with a dramatic reduction in the joint line, while no abnormalities were evident in the knee. The humeral deltoid tuberosity was significantly reduced in size in the Myf5nlacZ/nlacZ:MyoD−/− mutants while a change in shape but not in size was found in the humeral tuberosities of the Pax3Sp/Sp mutants. We also examined skeletal development in a ‘reduced muscle’ model, the Myf5nlacZ/+:MyoD−/− mutant, in which skeletal muscle forms but with reduced muscle mass. The reduced muscle phenotype appeared to have an intermediate effect on skeletal development, with reduced bone formation in the scapula and humerus compared to controls, but not in other rudiments. In summary, we have demonstrated that skeletal development is differentially affected by the lack of skeletal muscle, with certain rudiments and joints being more severely affected than others. These findings indicate that the response of skeletal progenitor cells to biophysical stimuli may depend upon their location in the embryonic limb, implying a complex interaction between mechanical forces and location-specific regulatory factors affecting bone and joint development.

VH gene usage by family members affected with chronic lymphocytic leukaemia

The excess risk of chronic lymphocytic leukaemia (CLL) in the first‐degree relatives of affected patients suggests that familial CLL might constitute a useful model to study the pathogenesis of this disease, as has been demonstrated in numerous other neoplastic disorders. Previous studies have shown non‐random utilization of immunoglobulin genes in CLL, some germline in sequence and others containing numerous somatic mutations. To investigate whether familial cases of CLL exhibit similarities in the composition of the B‐cell receptor repertoire to the pattern expressed by CLL patients as a whole, we have studied 25 CLL patients belonging to 12 different families (four French and eight Italian), each of which contained at least two affected members.

Can isotype switch modulate antigen-binding affinity and influence clonal selection?

Four different monoclonal Ig (MIg) (IgA1κ, IgG1κ, IgG2κ and IgG4κ) displaying anti‐tubulin activity were detected in the serum from a lymphoma patient. The complete sequence of three of these MIg showed identical VH and VL domains and the presence of mutations compatible with an antigen‐driven process. Surprisingly, despite complete homology in their variable domains, IgA1κ, IgG1κ, or their Fab fragments bound to a common motif recognized in β tubulin, with significant differences in affinity (IgA1κ 1.52×10–8 M, and IgG1κ 2.09×10–7 M). To substantiate these results, the VH and VL domains from IgA1κ were cloned and introduced into expression vectors containing the constant κ exon and either the μ or the γ1 constant exon, and complete recombinant IgMκ and IgG1κ were obtained. Like the IgA1κ, the IgMκ construction bound to the tubulin epitope with consistent affinity (7.7×10–9 M), whereas the IgG1κ construction displayed a significantly lower affinity (3.28×10–7 M). These results provide definitive evidence that isotype can influence binding affinity to antigen and suggest that malignant transformation occurred at the germinal center once the mutational process was achieved and the switch process was still active.

Do CLL B cells correspond to naive or memory B-lymphocytes? Evidence for an active Ig switch unrelated to phenotype expression and Ig mutational pattern in B-CLL cells

Recent work suggests that chronic lymphocytic leukemia (B-CLL) expressing unmutated immunoglobulin V genes could correspond to the proliferation of naive B cells whereas those expressing mutated genes, may correspond to the proliferation of post-germinal center B cells. Current data from gene profiling expression have failed to demonstrate a clear-cut distinction between these two forms of B-CLL disease. In the present study, we have investigated the complete VH nucleotide sequence and the presence of RNA transcripts from different CH domains in 25 B-CLL patients. Our results demonstrate that: (1) expression of IgD is not related to the mutational frequency and activation of the isotype switch pathway; (2) isotype switch, leading to simultaneous expression at the transcriptional and protein level of IgM, IgD, IgG and IgA, occurs in a small percentage of patients, and (3) different mechanisms such as VDJ duplication and trans-splicing or RNA splicing of long nuclear transcript, could be involved in isotype switch. Our results highlight the difficulty in assigning a normal counterpart to B-CLL cells and raise the possibility that a different B cell development pathway, independent from classical germinal centers, might exist in B-CLL.

Embryonic founders of adult muscle stem cells are primed by the determination gene Mrf4.

Skeletal muscle satellite cells play a critical role during muscle growth, homoeostasis and regeneration. Selective induction of the muscle determination genes Myf5, Myod and Mrf4 during prenatal development can potentially impact on the reported functional heterogeneity of adult satellite cells. Accordingly, expression of Myf5 was reported to diminish the self-renewal potential of the majority of satellite cells. In contrast, virtually all adult satellite cells showed antecedence of Myod activity. Here we examine the priming of myogenic cells by Mrf4 throughout development. Using a Cre-lox based genetic strategy and novel highly sensitive Pax7 reporter alleles compared to the ubiquitous Rosa26-based reporters, we show that all adult satellite cells, independently of their anatomical location or embryonic origin, have been primed for Mrf4 expression. Given that Mrf4Cre and Mrf4nlacZ are active exclusively in progenitors during embryogenesis, whereas later expression is restricted to differentiated myogenic cells, our findings suggest that adult satellite cells emerge from embryonic founder cells in which the Mrf4 locus was activated. Therefore, this level of myogenic priming by induction of Mrf4, does not compromise the potential of the founder cells to assume an upstream muscle stem cell state. We propose that embryonic myogenic cells and the majority of adult muscle stem cells form a lineage continuum.

Biophysical stimuli induced by passive movements compensate for lack of skeletal muscle during embryonic skeletogenesis

In genetically modified mice with abnormal skeletal muscle development, bones and joints are differentially affected by the lack of skeletal muscle. We hypothesise that unequal levels of biophysical stimuli in the developing humerus and femur can explain the differential effects on these rudiments when muscle is absent. We find that the expression patterns of four mechanosensitive genes important for endochondral ossification are differentially affected in muscleless limb mutants, with more extreme changes in the expression in the humerus than in the femur. Using finite element analysis, we show that the biophysical stimuli induced by muscle forces are similar in the humerus and femur, implying that the removal of muscle contractile forces should, in theory, affect the rudiments equally. However, simulations in which a displacement was applied to the end of the limb, such as could be caused in muscleless mice by movements of the mother or normal littermates, predicted higher biophysical stimuli in the femur than in the humerus. Stimuli induced by limb movement were much higher than those induced by the direct application of muscle forces, and we propose that movements of limbs caused by muscle contractions, rather than the direct application of muscle forces, provide the main mechanical stimuli for normal skeletal development. In muscleless mice, passive movement induces unequal biophysical stimuli in the humerus and femur, providing an explanation for the differential effects seen in these mice. The significance of these results is that forces originating external to the embryo may contribute to the initiation and progression of skeletal development when muscle development is abnormal.

Idiotype-pulsed dendritic cells are able to induce antitumoral cytotoxic CD8 cells in chronic lymphocytic leukaemia

Summary. Idiotypic structures of immunoglobulins from malignant B cells constitute tumour‐specific antigens, though the function of immunoglobulin‐specific CD8+ T cells in disease control and rejection remains unclear. We have studied five cases of B chronic lymphocytic leukaemia patients affected with indolent (three patients) or aggressive (two patients) disease. We showed that CD8+ T cells with major histocompatibility complex class I‐restricted cytotoxicity against autologous tumour B cells could be generated following repeated stimulations with idiotype‐pulsed dendritic cells in vitro. CD8+ T‐cell lines were able to upregulate CD69 expression and to release interferon (IFN)‐γ upon contact with the autologous B cells, though cytolytic activity was only substantiated for patients with indolent disease. The failure of cytolytic activity in patients with aggressive disease may be explained by a skewed maturation of memory CD8 cells.

Evidence for an antigen-driven selection process in human autoantibodies against acetylcholine receptor

Autoantibodies to the nicotinic acetylcholine receptor (AChR) play a central role in the neurological symptoms associated with myasthenia gravis (MG). A better knowledge of the structural organization and of the mechanisms leading to the production of these antibodies may help in understanding the pathogenesis of the disease. To achieve this, four IgG anti-AChR monoclonal autoantibodies obtained in a previous work were derived from lymphoid cells of MG patients. Two of them (MH1 and MH6) were capable of modulating in vitro the expression of AChR at the surface of TE-671 cells. We report here the complete nucleotide sequence of the heavy and light chains of these four antibodies. Although it is difficult to address the issue of VH gene usage in anti-AChR autoantibodies because of the limited number of clones studied, our results associated with others which have appeared in the literature point to non-stochastic usage by anti-AChR antibody of some defined VH genes belonging to VH2 and VH5 minifamilies overexpressed in the fetal repertoire. The second and major aim of this work was to assess the role of an antigen-driven selection process in the production of anti-AChR autoantibodies. When comparing the expressed sequences to their closest germline counterparts, it appeared that all four studied clones displayed numerous mutations in VH regions. In particular, MH1 and MH6, characterized by their AChR modulating capacity, displayed a higher than expected number of mutations and replacements occurring in CDR regions. These data point to an antigen-driven selection process. On the contrary, the mutational process observed in the MH% clone was borderline and that of MH7 was compatible with a random process. Interestingly, when comparing mutations in heavy and light chains, a significantly lower number of mutations were expressed in light chains for the four clones.

Somatic mutations can lead to a loss of superantigenic and polyreactive binding

Although antibodies have been assumed to bind a specific antigen, evidence exists showing that a single antibody can bind to multiple unrelated antigens. We previously studied a human monoclonal antibody expressing a mutated form of the VH3–73 gene and displaying anti‐tubulin activity in a patient suffering from an immunocytic lymphoma. Despite its expression of a VH3 family member, this immunoglobulin failed to react with protein A (SpA), suggesting that somatic mutations could account for its change in specificity. To examine this possibility, we produced recombinant Ig expressing germ‐line (IgMκ‐Germ) or the mutated form (IgMκ‐PER) of the VH3–73 fragment. Comparison of the respective affinities of the two Ig demonstrated that IgMκ‐Germ restores its SpA‐binding capacity, and shows a moderate decrease in its affinity for tubulin. Interestingly, IgMκ‐Germ displayed polyreactive specificity for different autoantigens, which contrasted to the monospecific binding of IgMκ‐PER to tubulin. These results suggest that the monoreactive IgMκ‐PER antibody may be derived from a natural polyreactive antibody through somatic mutation. In addition, both temperature modification and mild denaturation succeeded in recovering the polyreactivity of IgMκ‐PER, which favors the view that conformational modifications of the tertiary structure of antibodies may play a key role in the genesis of polyreactivity.