Multicolor strategies for investigating clonal expansion and tissue plasticity.

Understanding the generation of complexity in living organisms requires the use of lineage tracing tools at a multicellular scale. In this review, we describe the different multicolor strategies focusing on mouse models expressing several fluorescent reporter proteins, generated by classical (MADM, Brainbow and its multiple derivatives) or acute (StarTrack, CLoNe, MAGIC Markers, iOn, viral vectors) transgenesis. After detailing the multi-reporter genetic strategies that serve as a basis for the establishment of these multicolor mouse models, we briefly mention other animal and cellular models (zebrafish, chicken, drosophila, iPSC) that also rely on these constructs. Then, we highlight practical applications of multicolor mouse models to better understand organogenesis at single progenitor scale (clonal analyses) in the brain and briefly in several other tissues (intestine, skin, vascular, hematopoietic and immune systems). In addition, we detail the critical contribution of multicolor fate mapping strategies in apprehending the fine cellular choreography underlying tissue morphogenesis in several models with a particular focus on brain cytoarchitecture in health and diseases. Finally, we present the latest technological advances in multichannel and in-depth imaging, and automated analyses that enable to better exploit the large amount of data generated from multicolored tissues.

The epitope associated with the binding of the capsular polysaccharide of the group B meningococcus and of Escherichia coli K1 to a human monoclonal macroglobulin, IgMNOV.

The fine structure of the combining site of human mAb IgMNOV to poly-alpha(2----8)linked NeuNAc, the epitope of the group B meningococcal and E. coli K1 polysaccharides, has been probed using RIA and ELISA. Inhibition by oligomers ranging from 2 to 12 residues was used to assay binding to IgMNOV by group B meningococcal polysaccharide preparations (GBMP) or by poly(A). The inhibitory properties of the oligomers were almost identical in both assays of the binding of GBMP to horse IgM (H46). This evidence and the finding that both GBMP and poly(A) precipitated IgMNOV equally per unit weight indicated that the epitope of poly(A) must mimic an equivalent epitope on GBMP despite the absence of any apparent common structural features in the two molecules. Unlike most carbohydrate-anticarbohydrate systems in which the site is saturated by oligomers of up to six or seven sugars, all the anti-alpha(2----8)NeuNAc systems above required much larger oligomers. Because these oligomers are larger than the maximum size of an antibody site the epitope must be conformationally controlled, and this has been confirmed by nuclear magnetic resonance spectroscopy. However, despite the above similarities, GBMP and poly(A) were differentiated in that only GBMP bound to H46. Smaller linear molecules obtained by delipidating the GBMP, as well as periodate-oxidized GBMP with its nonreducing end oxidized or linked covalently to BSA, bound to and precipitated IgMNOV and H46. This showed that, despite their differences, terminal nonreducing ends were not involved and that both epitopes were located in the conformationally controlled inner residues of the GBMP. The difference thus must reside in the ability of IgMNOV and H46 to recognize different structural aspects of the same conformationally controlled inner residues. The ELISA data indicate that both IgMNOV and H46 have groove-type sites that bind exclusively to an epitope located on the acidic side of the inner residues. The differences determining the ability of IgMNOV and the failure of H46 to cross-react with poly(A), poly(I), and denatured DNA, may depend on differences in the degree of protonation required by each antibody, and this may be clarified by a study of the effects of pH on the precipitin behavior of IgMNOV and H46.

Sox2 Controls Periderm and Rugae Development to Inhibit Oral Adhesions.

In humans, ankyloglossia and cleft palate are common congenital craniofacial anomalies, and these are regulated by a complex gene regulatory network. Understanding the genetic underpinnings of ankyloglossia and cleft palate will be an important step toward rational treatment of these complex anomalies. We inactivated the Sry (sex-determining region Y)-box 2 (Sox2) gene in the developing oral epithelium, including the periderm, a transient structure that prevents abnormal oral adhesions during development. This resulted in ankyloglossia and cleft palate with 100% penetrance in embryos examined after embryonic day 14.5. In Sox2 conditional knockout embryos, the oral epithelium failed to differentiate, as demonstrated by the lack of keratin 6, a marker of the periderm. Further examination revealed that the adhesion of the tongue and mandible expressed the epithelial markers E-Cad and P63. The expanded epithelia are Sox9-, Pitx2-, and Tbx1-positive cells, which are markers of the dental epithelium; thus, the dental epithelium contributes to the development of oral adhesions. Furthermore, we found that Sox2 is required for palatal shelf extension, as well as for the formation of palatal rugae, which are signaling centers that regulate palatogenesis. In conclusion, the deletion of Sox2 in oral epithelium disrupts palatal shelf extension, palatal rugae formation, tooth development, and periderm formation. The periderm is required to inhibit oral adhesions and ankyloglossia, which is regulated by Sox2. In addition, oral adhesions occur through an expanded dental epithelial layer that inhibits epithelial invagination and incisor development. This process may contribute to dental anomalies due to ankyloglossia.

Immunogenicity in animals of a polysaccharide-protein conjugate vaccine against type III group B Streptococcus.

The native capsular polysaccharide of type III group B Streptococcus elicits a specific antibody response in only 60% of nonimmune human subjects. To enhance the immunogenicity of this polysaccharide, we coupled the type III polysaccharide to tetanus toxoid. Prior to coupling, aldehyde groups were introduced on the polysaccharide by controlled periodate oxidation, resulting in the conversion of 25% of the sialic acid residues of the polysaccharide to residues of the 8-carbon analogue of sialic acid, 5-acetamido-3,5-dideoxy-D-galactosyloctulosonic acid. Tetanus toxoid was conjugated to the polysaccharide by reductive amination, via the free aldehyde groups present on the partially oxidized sialic acid residues. Rabbits vaccinated with the conjugate vaccine produced IgG antibodies that reacted with the native type III group B streptococcal polysaccharide (3/3 rabbits), while rabbits immunized with the unconjugated type III polysaccharide failed to respond (0/3 rabbits). Sera from animals receiving conjugate vaccine opsonized type III group B streptococci for phagocytic killing by human peripheral blood leukocytes, and protected mice against lethal challenge with live type III group B streptococci. The results suggest that this method of conjugation to a carrier protein may be a useful strategy to improve the immunogenicity of the type III group B Streptococcus polysaccharide in human subjects.

Effects of chain length on the immunogenicity in rabbits of group B Streptococcus type III oligosaccharide-tetanus toxoid conjugates.

One method to improve the immunogenicity of polysaccharide antigens is the covalent coupling of the native polysaccharide or a derivative oligosaccharide to a carrier protein. In general, T cell-dependent properties are enhanced in conjugates of smaller saccharides, but a conformational epitope of the native polysaccharide may be better expressed in conjugates of larger saccharides. We have reported previously the synthesis and immunogenicity in animals of an oligosaccharide-tetanus toxoid conjugate vaccine against type III group B Streptococcus. In this study, we sought to determine the optimal size of group B Streptococcus type III oligosaccharide for use in a conjugate vaccine by evaluating the relative immunogenicity of conjugate vaccines containing oligosaccharides that were twofold smaller (7,000 Mr) or larger (27,000 Mr) than that reported previously (14,500 Mr). All three type III oligosaccharide conjugate vaccines were immunogenic in rabbits, in contrast to native, uncoupled group B Streptococcus type III polysaccharide. However, with respect to eliciting specific antibodies that were protective in vivo, the vaccine containing the intermediate-size oligosaccharide was superior to the smaller or larger conjugate vaccine. Analysis of opsonic activity of vaccine-induced antibodies demonstrated a predominance of IgG antibodies, thought to reflect T cell dependence, in response to shorter chain length conjugates, while the conformational epitope of the native polysaccharide was maximally expressed on longer chain length conjugates. These opposing trends may account for the optimal immunogenicity of an intermediate-size group B Streptococcus type III oligosaccharide conjugate vaccine.

Use of defined oligosaccharide epitopes in an ELISA for group B streptococcus.

A single-site ELISA for group B streptococcal polysaccharide based on a monoclonal antibody against an immunodominant trirhamnoside epitope was inhibited at high capture antibody coating densities. The inhibition was eliminated when less antibody was coated or when high antigen concentrations were tested. This antigen is polyvalent with respect to the terminal trirhamnoside epitope and therefore it appears that closely spaced capture antibodies bound the epitope completely, leaving no sites for attachment of the enzyme-labeled second antibody with the same specificity. To make use of the trirhamnoside epitope feasible, a two-site ELISA was evaluated with this monoclonal antibody and a polyclonal antibody isolated by affinity chromatography. ELISA inhibition studies using oligosaccharides derived from the group B polysaccharide were used to evaluate the specificity of the polyclonal antibody. This showed that the antibody recognized both alpha-L-rhamnose (1----3)-D-galactose and alpha-L-rhamnose(1----3)-D-glucitol side chains, which together represent 30 potential binding sites per antigen molecule. A two-site ELISA with the anti-trirhamnoside monoclonal antibody to capture the antigen and the polyclonal antibody as enzyme conjugated second antibody reacted with only group B streptococci when tested against a panel of bacteria representative of the vaginal flora and was able to detect 3 x 10(4) cfu/test of group B streptococci. This two-site ELISA, based on well defined oligosaccharide epitopes had the sensitivity and specificity necessary to identify women at risk of infecting their newborns with group B streptococcus.

Hydrolytic release, and identification by g.l.c.-m.s., of 3-deoxy-D-manno-2-octulosonic acid in the lipopolysaccharides isolated from bacteria of the Vibrionaceae.

The identification of the peracetylated methyl glycosides of 3-deoxy-D-manno-2-octulosonic acid (KDO) methyl esters was achieved by g.l.c.-m.s. These peracetylated methyl glycoside methyl esters were obtained from fully acetylated lipopolysaccharides and core oligosaccharides of representative strains of the Vibrionaceae family by the following sequence of mild reactions: acetolysis, methanolysis, and acetylation. KDO was shown to be present in all of the lipopolysaccharides (LPS), a result in direct contrast to the generally accepted view of the absence of this compound in LPS from this family of bacteria.

Analysis of oligosaccharide epitopes of meningococcal lipopolysaccharides by fast-atom-bombardment mass spectrometry.

A mass-spectrometric approach is presented for the analysis of the structures of lipopolysaccharide-derived oligosaccharides, which are frequently difficult to define by classical methods since they contain chemically labile components. The method involves f.a.b.-m.s. of the oligosaccharides, their peracetylated and permethylated derivatives, their deuterioacetylated and methylated analogues, and the fragments obtained during graded methanolysis of the methylated analogues. Data obtained from two representative meningococcal LPS oligosaccharides define the sequence, patterns of branching, and the extent and location of the phosphorylethanolamine and O-acetyl substituents.

Phagocytic, serological, and protective properties of streptococcal group A carbohydrate antibodies.

Group A streptococcal antibodies promote phagocytosis of several different strains of GR A streptococci. These antibodies passively protect against an in vivo mouse challenge model.

Structure activity studies on group C meningococcal polysaccharide-protein conjugate vaccines: effect of O-acetylation on the nature of the protective epitope.

A series of group C meningococcal polysaccharide-tetanus toxoid (GCMP-TT) conjugates were prepared as vaccines with varying percentages of O-acetylation at the C-7 and C-8 positions of sialic acid residues in the polysaccharide (PS). The immune response in mice was highly dependent on the degree of O-acetylation. Less O-acetylation resulted in higher serum bactericidal activity (SBA) towards the O-acetylated (OA) meningococcal strain, C11. In addition, since an unconjugated de-O-acetylated (dOA) GCMP vaccine was previously shown to be highly immunogenic in humans, we had chosen this dOA form to couple with TT by reductive amination for clinical evaluation. This conjugate vaccine was shown to be well-tolerated and highly immunogenic in adults, children, and infants in the UK. To understand the nature of the GCMP protective epitope, a series of spectroscopic and serological studies were conducted, using high resolution H-NMR spectroscopy at 500 MHz and competitive inhibition SBA assays. The dOA GCMP was 10-1000 times better at inhibiting the SBA for an OA strain than the OA GCMP, suggesting that the GCMP-based protective epitope on the bacterium exists in a dOA form. In addition, SBA for an OA strain is highly correlated with dOA GCMP-specific IgG. NMR data on freshly isolated GCMP indicated that, on the surface of the organism, most of the O-acetylation exists at position C-8, with some regions containing dOA or OA C-7 sialic acid. After extraction of PS and storage in solution, most of the O-acetyl groups migrate to C-7, leaving an epitope that is conformationally related, but not quite identical (due to the presence of the O-acetyl group), to the one contained in the dOA PS. We speculate that the role of the O-acetyl group at the C-8 position of the PS on the organism is to form less immunogenic epitopes, or mask the protective epitope, and thus escape immune surveillance. The dOA form of the vaccine may therefore provide better protection against group C meningococcal disease than the OA form by eliciting a greater proportion of functional antibodies that are directly aimed at the protective epitope.

[Long-term peridural morphine analgesia in neoplastic and vascular pathology]. / Analgésie péridurale morphinique de longue durée en pathologie néoplasique et vasculaire.

Epidural analgesia using morphine has been used on 44 patients with intractable chronic pain, resistant to analgesics (including opiates). The pain was due to cancer in 24 cases, of vascular origin in 20. An indwelling tunnelized epidural catheter afforded repeated injections of morphine for a long period (up to 129 days) either in hospital or at home. The quality of analgesia achieved was rated as excellent or good, in 68 p. 100 of cases. Two cases only were total failures. Side effects, relatively common, were usually transient and minor; no case of respiratory depression or of infection has been recorded.

What is the biological basis of pattern formation of skin lesions?

Pattern recognition is at the heart of clinical dermatology and dermatopathology. Yet, while every practitioner of the art of dermatological diagnosis recognizes the supreme value of diagnostic cues provided by defined patterns of 'efflorescences', few contemplate on the biological basis of pattern formation in and of skin lesions. Vice versa, developmental and theoretical biologists, who would be best prepared to study skin lesion patterns, are lamentably slow to discover this field as a uniquely instructive testing ground for probing theoretical concepts on pattern generation in the human system. As a result, we have at best scraped the surface of understanding the biological basis of pattern formation of skin lesions, and widely open questions dominate over definitive answer. As a symmetry-breaking force, pattern formation represents one of the most fundamental principles that nature enlists for system organization. Thus, the peculiar and often characteristic arrangements that skin lesions display provide a unique opportunity to reflect upon--and to experimentally dissect--the powerful organizing principles at the crossroads of developmental, skin and theoretical biology, genetics, and clinical dermatology that underlie these--increasingly less enigmatic--phenomena. The current 'Controversies' feature offers a range of different perspectives on how pattern formation of skin lesions can be approached. With this, we hope to encourage more systematic interdisciplinary research efforts geared at unraveling the many unsolved, yet utterly fascinating mysteries of dermatological pattern formation. In short: never a dull pattern!

Chromium trioxide oxidation of acetylated 3-amino-3,6-dideoxy-L-hexosides.

Glycosides of the fully acetylated 3-amino-3,6-dideoxy-L-hexosides in the gluco, galacto, manno, and talo configurations have been treated with chromium trioxide in acetic acid. The alpha-L-methyl glycosides, which exist in the more stable chair conformation 1C4, with an axially oriented aglycon, are resistant to this oxidation, whereas the beta-L-linked glycoside having the gluco configuration (1C4 conformation) and the alpha-L-methyl glycoside having the talo configuration (4C1 conformation), both with equatorially oriented aglycons, are oxidized to the corresponding 5-adulosonates.

Conformational differences between linear alpha (2----8)-linked homosialooligosaccharides and the epitope of the group B meningococcal polysaccharide.

The alpha-(2----8)-linked sialic acid oligosaccharides (NeuAc)n exhibit an unusual degree of heterogeneity in the conformation of their linkages. This was diagnosed by observation in their 13C NMR spectra of an equivalent and unique heterogeneity in the chemical shifts of their anomeric carbons and subsequently confirmed by more comprehensive 1H and 13C NMR studies. In these studies both one-dimensional and two-dimensional experiments were carried out on the trisaccharide (NeuAc)3 and colominic acid. In addition to the unambiguous assignment of the signals in the spectra, these experiments demonstrated that both linkages of (NeuAc)3 differed in conformation from each other and from the inner linkages of colominic acid. The NMR data indicate that these conformational differences extend to both terminal disaccharides of oligosaccharides larger than (NeuAc)5, a result that has considerable physical and biological significance. In the context of the group B meningococcal polysaccharide, it provides an explanation for the conformational epitope of the group B meningococcal polysaccharide, which was proposed on the evidence that (NeuAc)10, larger than the optimum size of an antibody site, was the smallest oligosaccharide able to bind to group B polysaccharide specific antibodies. Because the two terminal disaccharides of (NeuAc)10 differ in conformation to its inner residues, the immunologically functional part of (NeuAc)10 resides in its inner six residues. This number of residues is now consistent with the maximum size of an antibody site.