Brigitte Delhomme

Characterization of the d-glucose/Na+ cotransport system in the intestinal brush-border membrane by using the specific substrate, methyl α-d-glucopyranoside

By using isolated membrane vesicles, we have investigated the tenet that D-glucose transport across the intestinal brush-border membrane involves at least two distinct, Na+-activated agencies (D-glucose transport systems S-1 and S-2), only one of which (S-1) can use methyl alpha-D-glucopyranoside (methyl alpha-glucoside) as a substrate. Our results with this glucose analogue show that: (a) As a function of time, methyl alpha-glucoside uptake exhibits a typical overshoot, similar to but smaller than that given by D-glucose with the same vesicle batch. (b) Nonlinear regression analysis of substrate-saturation curves reveals that, contrary to D-glucose, methyl alpha-glucoside transport involves a single transport system which we have identified as S-1. (c) Methyl alpha-glucoside exhibits an apparent affinity (defined as the reciprocal of Km) 4-times smaller than that of D-glucose for S-1 (Km(Dglucose) = 0.5 mM; Km(methyl alpha-glucoside) = 2 mM). However, methyl alpha-glucoside has a Vmax (230 pmol/mg protein per s) identical to that characterizing D-glucose transport by this system. (d) In the absence of Na+, methyl alpha-glucoside uptake is indistinguishable from simple diffusion, confirming that Na+ is an obligatory activator of S-1. (e) Phlorizin behaves as a fully competitive inhibitor of methyl alpha-glucoside transport (Ki = 18 microM), again indicating that S-1 is involved. (f) Neither phloretin nor cytochalasin B affects methyl alpha-glucoside uptake. We conclude that methyl alpha-glucoside is a substrate specific for S-1, which permits study of the properties of this system without interference by substrate fluxes taking place through any other channel.

Basonuclin 2 has a function in the multiplication of embryonic craniofacial mesenchymal cells and is orthologous to disco proteins

Basonuclin 2 is a recently discovered zinc finger protein of unknown function. Its paralog, basonuclin 1, is associated with the ability of keratinocytes to multiply. The basonuclin zinc fingers are closely related to those of the Drosophila proteins disco and discorelated, but the relation between disco proteins and basonuclins has remained elusive because the function of the disco proteins in larval head development seems to have no relation to that of basonuclin 1 and because the amino acid sequence of disco, apart from the zinc fingers, also has no similarity to that of the basonuclins. We have generated mice lacking basonuclin 2. These mice die within 24 h of birth with a cleft palate and abnormalities of craniofacial bones and tongue. In the embryonic head, expression of the basonuclin 2 gene is restricted to mesenchymal cells in the palate, at the periphery of the tongue, and in the mesenchymal sheaths that surround the brain and the osteocartilagineous structures. In late embryos, the rate of multiplication of these mesenchymal cells is greatly diminished. Therefore, basonuclin 2 is essential for the multiplication of craniofacial mesenchymal cells during embryogenesis. Non-Drosophila insect databases available since 2008 reveal that the basonuclins and the disco proteins share much more extensive sequence and gene structure similarity than noted when only Drosophila sequences were examined. We conclude that basonuclin 2 is both structurally and functionally the vertebrate ortholog of the disco proteins. We also note the possibility that some human craniofacial abnormalities are due to a lack of basonuclin 2.

Metabolic effects of high-protein diets in Zucker rats☆

The effects of dietary protein on the metabolism of proteins, carbohydrates, and especially, lipids were investigated in genetically obese Zucker rats and their lean siblings. For 40 days the rats received diets containing 15%, 64%, or 82% protein, included at the expense of cornstarch. In the obese animals, the high-protein diets led to decreased food intake and weight gain. While these diets decreased the activities of lipogenic enzymes along with the lipid gain, they did not decrease the final body-fat content. The increase protein intake stimulated hepatic ureogenesis and gluconeogenesis. Lipolysis was stimulated, as demonstrated by an accumulation of ketone bodies in the liver. Blood levels of triacylglycerols, free glycerol, and nonesterified fatty acids were concomitantly decreased, which suggests an accelerated turnover of lipids. Whatever the composition of the diet, total energy retention of the lean rats was always less than that of the obese rats. The changes observed on high-protein diets were essentially the same for the two groups, except that the final body-content of lipids in the lean rats was significantly lower. In the absence of exogenous carbohydrate, the lean rats were barely able to retain nitrogen and to maintain hepatic lipogenesis. Unlike the rats from other strains, the lean Zucker rats could not adapt to a low-carbohydrate diet; this failure may be due to a metabolic disorder.

Human balanced translocation and mouse gene inactivation implicate Basonuclin 2 in distal urethral development

We studied a man with distal hypospadias, partial anomalous pulmonary venous return, mild limb-length inequality and a balanced translocation involving chromosomes 9 and 13. To gain insight into the etiology of his birth defects, we mapped the translocation breakpoints by high-resolution comparative genomic hybridization (CGH), using chromosome 9- and 13-specific tiling arrays to analyze genetic material from a spontaneously aborted fetus with unbalanced segregation of the translocation. The chromosome 13 breakpoint was ∼400 kb away from the nearest gene, but the chromosome 9 breakpoint fell within an intron of Basonuclin 2 (BNC2), a gene that encodes an evolutionarily conserved nuclear zinc-finger protein. The BNC2/Bnc2 gene is abundantly expressed in developing mouse and human periurethral tissues. In all, 6 of 48 unrelated subjects with distal hypospadias had nine novel nonsynonymous substitutions in BNC2, five of which were computationally predicted to be deleterious. In comparison, two of 23 controls with normal penile urethra morphology, each had a novel nonsynonymous substitution in BNC2, one of which was predicted to be deleterious. Bnc2−/− mice of both sexes displayed a high frequency of distal urethral defects; heterozygotes showed similar defects with reduced penetrance. The association of BNC2 disruption with distal urethral defects and the genes expression pattern indicate that it functions in urethral development.

The zinc-finger protein basonuclin 2 is required for proper mitotic arrest, prevention of premature meiotic initiation and meiotic progression in mouse male germ cells

Absence of mitosis and meiosis are distinguishing properties of male germ cells during late fetal and early neonatal periods. Repressors of male germ cell meiosis have been identified, but mitotic repressors are largely unknown, and no protein repressing both meiosis and mitosis is known. We demonstrate here that the zinc-finger protein BNC2 is present in male but not in female germ cells. In testis, BNC2 exists as several spliced isoforms and presumably binds to DNA. Within the male germ cell lineage, BNC2 is restricted to prospermatogonia and undifferentiated spermatogonia. Fetal prospermatogonia that lack BNC2 multiply excessively on embryonic day (E)14.5 and reenter the cell cycle prematurely. Mutant prospermatogonia also engage in abnormal meiosis; on E17.5, Bnc2−/− prospermatogonia start synthesizing the synaptonemal protein SYCP3, and by the time of birth, many Bnc2−/− prospermatogonia have accumulated large amounts of nonfilamentous SYCP3, thus appearing to be blocked at leptonema. Bnc2−/− prospermatogonia do not undergo proper male differentiation, as they lack almost all the mRNA for the male-specific methylation protein DNMT3L and have increased levels of mRNAs that encode meiotic proteins, including STRA8. Bnc2−/− prospermatogonia can produce spermatogonia, but these enter meiosis prematurely and undergo massive apoptotic death during meiotic prophase. This study identifies BNC2 as a major regulator of male germ stem cells, which is required for repression of meiosis and mitosis in prospermatogonia, and for meiosis progression during spermatogenesis. In view of the extreme evolutionary conservation of BNC2, the findings described here are likely to apply to many species.

Different Temperature Sensitivity and Cation Specificity of Two Distinct d‐Glucose/Na+ Cotransport Systems in the Intestinal Brush‐Border Membranea

Recently, we proposed’ a general model for organic solute and N a + cotransport based on two key premises: (1) N a + is an obligatory (essential) activator and (2) because net transfer of a positive charge occurs, V,,, should be a function of A+. To test this working hypothesis, we studied D-glucose uptake in the presence and in the absence of Na+, using isolated brush-border membrane vesicles, which permit controlling the composition of the medium a t each side of the membrane. The experimental setup (see the illustration legends for details) included either an alkali-metal chloride salt giving an (out)/(in) = 100/0 m M concentration gradient, or no metal ion at all. In the absence of Na+, D-glucose uptake rates decreased but nevertheless indicated the existence of stereospecific transport. The activating sequence was: Na+ >> Li+ > K+ = sorbitol. However, these results required further clarification because of recent evidence showing that there are two distinct sodiumdependent glucose transport systems in guinea pig jejunum.* Frequently, transport is classified into “sodium-dependent’’ and “sodium-independent,” the implication being that separate transport systems are involved under either condition. However, this distinction seems gratuitous in the absence of a solid understanding of the mechanism(s) of glucose uptake under sodium-free conditions. Rather, the correct question is: To what extent does a sodium-dependent system remain operational when the ‘‘main,” but not necessarily “obligatory” activator, Na+, is absent? To answer this question, we carried out glucose saturation curves at either 25OC or at 35OC. When Na+ is present, a t 35O, our results demonstrate the existence of two distinct (saturable) glucose transport systems, apart from the diffusion component, Kd [S]. In contrast, a t 25O one of these two systems was not readily manifest. We noticed, however, that the apparent value of Kd (given by the slope of the saturation curve a t high [S]; see FIG. 1) is more than twice as large at 2 5 O as a t 35O, strongly suggesting that it hides a very low-affinity second transport system. In effect, if for that system K,,, >> [S], then the corresponding Michaelian term would simplify to: v = (V,,JK,) [S] = k [S]. The experimentally observed diffusion constant would in that case be the sum of two factors: pd = Kd + k. When we fixed Kd to its “true” value (see TABLE l ) , the second system at 25” became patent, showing a negligibly small affinity

The importance of basonuclin 2 in adult mice and its relation to basonuclin 1

BNC2 is an extremely conserved zinc finger protein with important functions in the development of craniofacial bones and male germ cells. Because disruption of the Bnc2 gene in mice causes neonatal lethality, the function of the protein in adult animals has not been studied. Until now BNC2 was considered to have a wider tissue distribution than its paralog, BNC1, but the precise cell types expressing Bnc2 are largely unknown. We identify here the cell types containing BNC2 in the mouse and we show the unexpected presence of BNC1 in many BNC2-containing cells. BNC1 and BNC2 are colocalized in male and female germ cells, ovarian epithelial cells, sensory neurons, hair follicle keratinocytes and connective cells of organ capsules. In many cell lineages, the two basonuclins appear and disappear synchronously. Within the male germ cell lineage, BNC1 and BNC2 are found in prospermatogonia and undifferentiated spermatogonia, and disappear abruptly from differentiating spermatogonia. During oogenesis, the two basonuclins accumulate specifically in maturing oocytes. During the development of hair follicles, BNC1 and BNC2 concentrate in the primary hair germs. As follicle morphogenesis proceeds, cells possessing BNC1 and BNC2 invade the dermis and surround the papilla. During anagen, BNC1 and BNC2 are largely restricted to the basal layer of the outer root sheath and the matrix. During catagen, the compartment of cells possessing BNC1 and BNC2 regresses, and in telogen, the two basonuclins are confined to the secondary hair germ. During the next anagen, the BNC1/BNC2-containing cell population regenerates the hair follicle. By examining Bnc2(-/-) mice that have escaped the neonatal lethality usually associated with lack of BNC2, we demonstrate that BNC2 possesses important functions in many of the cell types where it resides. Hair follicles of postnatal Bnc2(-/-) mice do not fully develop during the first cycle and thereafter remain blocked in telogen. It is concluded that the presence of BNC2 in the secondary hair germ is required to regenerate the transient segment of the follicle. Postnatal Bnc2(-/-) mice also show severe dwarfism, defects in oogenesis and alterations of palatal rugae. Although the two basonuclins possess very similar zinc fingers and are largely coexpressed, BNC1 cannot substitute for BNC2. This is shown incontrovertibly in knockin mice expressing Bnc1 instead of Bnc2 as these mice invariably die at birth with craniofacial abnormalities undistinguishable from those of Bnc2(-/-) mice. The function of the basonuclins in the secondary hair germ is of particular interest.