Proteins That Promote Filopodia Stability, but Not Number, Lead to More Axonal-Dendritic Contacts

Dendritic filopodia are dynamic protrusions that are thought to play an active role in synaptogenesis and serve as precursors to spine synapses. However, this hypothesis is largely based on a temporal correlation between filopodia formation and synaptogenesis. We investigated the role of filopodia in synapse formation by contrasting the roles of molecules that affect filopodia elaboration and motility, versus those that impact synapse induction and maturation. We used a filopodia inducing motif that is found in GAP-43, as a molecular tool, and found this palmitoylated motif enhanced filopodia number and motility, but reduced the probability of forming a stable axon-dendrite contact. Conversely, expression of neuroligin-1 (NLG-1), a synapse inducing cell adhesion molecule, resulted in a decrease in filopodia motility, but an increase in the number of stable axonal contacts. Moreover, RNAi knockdown of NLG-1 reduced the number of presynaptic contacts formed. Postsynaptic scaffolding proteins such as Shank1b, a protein that induces the maturation of spine synapses, increased the rate at which filopodia transformed into spines by stabilization of the initial contact with axons. Taken together, these results suggest that increased filopodia stability and not density, may be the rate-limiting step for synapse formation

A monoclonal V kappa l light chain responsible for incomplete proximal tubulopathy.

Calcium and phosphate metabolism abnormalities are frequent in myeloma patients and the role of renal lesions in such ionic perturbations may have been overlooked. The authors herein report the complete primary structure of a Bence Jones Vkappal light chain responsible for myeloma-associated proximal tubulopathy with increased phosphaturia. Plasma and serum biochemical evaluations indicated a proximal tubular dysfunction mainly manifested as tubular acidosis and phosphate loss. The study of a kidney biopsy showed interstitial and tubular lesions with numerous myeloma casts and peculiar features of the proximal tubular cells, which carried numerous phagolysosomal inclusions with occasional crystalline periodic striation. The nephrotoxic light chain primary structure was deduced from the bone marrow monoclonal plasma cells RNA. The kappal sequence was highly homologous to kappa chains previously characterized in patients with Fanconi syndrome. It was related to the Vkappal subgroup and was composed of a variable segment encoded by the O8/O18 germline gene rearranged to Jkappa4. The primary sequence presented unusual features restricted to the variable region, including substitutions of residues 28 and 31 in the complementary determining region 1 (CDR1) by amino acids of different charge. An unusual conformation of the kappal domain, likely resulting from somatic hypermutation, could alter the catabolism of the protein after its internalization and result in the tubular cell dysfunction. Comparison with Fanconi syndrome studies suggests that Vkappal Bence Jones proteins may damage proximal tubular cells to an extent varying according to light chain (LC) sequence and structure, either leading to crystal formation and Fanconi syndrome or inducing partial inhibition of proximal tubule function

B cell development arrest upon insertion of a neo gene between JH and Emu: promoter competition results in transcriptional silencing of germline JH and complete VDJ rearrangements.

Previous targeting experiments within the IgH locus have shown that V(D)J recombination was affected by an insertion of a neo gene within E(mu) upstream of the core enhancer, but not by insertions downstream of the enhancer. Similarly, class switch recombination to a given (C) gene was affected only by interposition of neo in between that gene and the 3' IgH enhancers. Here we show that insertion of neo upstream E(mu) only marginally impairs V(D)J recombination, but results in an altered D and J(H) gene usage and completely blocks transcription of the germline J(H) region and the rearranged VDJ segments. Although transcriptional silencing of J(H) occurs upstream of the insertion and results in the lack of mature B cells in homozygous mutant animals, IgH transcription is maintained downstream of the insertion together with neo transcription and can be up-regulated by LPS stimulation or upon fusion with plasmacytoma cells. Altogether these data argue for a polarized "neo effect" involving promoter competition and further show that V(D)J rearrangement can be uncoupled from transcription

The immunoglobulin heavy-chain locus hs3b and hs4 3' enhancers are dispensable for VDJ assembly and somatic hypermutation.

The more distal enhancers of the immunoglobulin heavy-chain 3' regulatory region, hs3b and hs4, were recently demonstrated as master control elements of germline transcription and class switch recombination to most immunoglobulin constant genes. In addition, they were shown to enhance the accumulation of somatic mutations on linked transgenes. Since somatic hypermutation and class switch recombination are tightly linked processes, their common dependency on the endogenous locus 3' enhancers could be an attractive hypothesis. VDJ structure and somatic hypermutation were analyzed in B cells from mice carrying either a heterozygous or a homozygous deletion of these enhancers. We find that hs3b and hs4 are dispensable both for VDJ assembly and for the occurrence of mutations at a physiologic frequency in the endogenous locus. In addition, we show that cells functionally expressing the immunoglobulin M (IgM) class B-cell receptor encoded by an hs3b/hs4-deficient locus were fully able to enter germinal centers, undergo affinity maturation, and yield specific antibody responses in homozygous mutant mice, where IgG1 antibodies compensated for the defect in other IgG isotypes. By contrast, analysis of Peyer patches from heterozygous animals showed that peanut agglutinin (PNAhigh) B cells functionally expressing the hs3b/hs4-deficient allele were dramatically outclassed by B cells expressing the wild-type locus and normally switching to IgA. This study thus also highlights the role of germinal centers in the competition between B cells for affinity maturation and suggests that membrane IgA may promote recruitment in an activated B-cell compartment, or proliferation of activated B cells, more efficiently than IgM in Peyer patches

Fanconi's syndrome induced by a monoclonal Vkappa3 light chain in Waldenstrom's macroglobulinemia.

Fanconi's syndrome (FS) is a disorder of sodium-dependent proximal tubule reabsorption, which may complicate plasma cell disorders producing a free monoclonal light chain (LC). FS often occurs in the setting of smoldering myeloma and features cytoplasmic crystalline inclusions of monoclonal kappa LC in proximal tubular cells and malignant plasma cells. Although the clinical and pathological presentation may vary, including lack of crystal formation, monoclonal kappa LCs that underlie FS show a striking genetic and biochemical homogeneity: they almost always belong to the Vkappa1 subgroup of variability and originate from 2 germline genes, O2/O12 or O8/O18. Their variable domain sequences present unusual hydrophobic residues, responsible for the resistance to proteolysis, which leads to LC accumulation in the endocytic compartment of proximal tubule cells. We report a patient with slowly progressive Waldenstrom's macroglobulinemia and full-blown FS with accumulation of a monoclonal kappa LC within proximal tubules, but no detectable crystalline organization. This LC, which belonged to the unusual Vkappa3 subgroup and derived from the L2/L16 germline gene, showed no common substitution with previously described FS kappaI LC and was sensitive to trypsin digestion. These data show that molecular and biochemical characteristics of kappa LCs in patients with FS are more heterogeneous than initially suspected. Mechanisms other than resistance of LCs to endosomal proteolysis probably are involved in the pathogenesis of FS-associated plasma cell dyscrasias

L’ovulation chez les mammifères

The triggering of ovulation in mammals can be done according to two modes: spontaneous and provoked. Spontaneous ovulation occurs during the estrous cycle as a result of internal endocrine factors. Induced ovulation is triggered by mating. In both cases, it is the increase in GnRH secretion that leads to an increase in LH that causes ovulation. The factors involved in the stimulation of GnRH secretion are different according to the two modalities, mainly kisspeptin for spontaneous ovulators and beta-NGF for provoked ovulators. Current protocols used to induce ovulation rely on a direct action on the ovary, through the use of heterologous gonadotropins, or by an action on the pituitary gland with GnRH agonists. These protocols present different disadvantages: loss of activity with time, supra-physiological stimulation, ethic questioning about the production of some of these products. New paradigms for triggering ovulation by targeting the hypothalamus, respectful of animal welfare and the environment are presented in this review. This review aims to introduce the reader to the cellular and molecular mechanisms involved in the regulation and triggering of ovulation as well as two new approaches that are being developed and that are respectful of the animal and of its environment.La maîtrise du moment de l’ovulation chez les mammifères d’élevage permet d’améliorer la fertilité, la gestion des mises bas, mais les méthodes actuelles sont basées sur l’utilisation de fortes doses d’hormones. Cette revue présente de nouveaux paradigmes pour maitriser le moment de l’ovulation, respectueux de la physiologie de l’animal, sans supplémentation hormonale basés sur la connaissance des mécanismes physiologiques