Finding novel Neural Crest regulators : Pfkfb4, a key glycolysis partner, controls Neural Crest early patterning in Xenopus laevis / A la découverte de nouveaux régulateurs de la Crête Neurale : Pfkfb4, un régulateur de la glycolyse, contrôle aussi le développement précoce de la Crête Neurale chez l’amphibien.

Pegoraro, Caterina

12 December 2012

La crête neurale (CN) est une population transitoire de cellules multipotentes qui émerge à la frontière entre l’ectoderme neural et non-neural, dans une région appelée la bordure neurale (BN). Lorsque la BN se soulève pour former le tube neural, les cellules de la CN subissent une transition épithélium-mésenchyme (TEM), et migrent de façon intensive dans l’ensemble de l’embryon pour atteindre leur destination finale et se différencier. Elles sont à l’origine de nombreux types de dérivés : neurones, cellules gliales, cartilage de la tête, os et tissus connectifs, cellules pigmentaires, cellules sympatho-adrenales. Tous ces processus sont régulés par l’action coordonnée de nombreux gènes qui forment un réseau de régulations génétiques complexe, au sein duquel de nombreuses interactions ont été décrites, même si de nombreuses relations restent à élucider à ce jour. Une mauvaise régulation de gènes normalement impliqués dans la formation de la CN provoque des malformations congénitales appelées neurocristopathies. Par ailleurs, la TEM subie par les cellules de CN avant leur migration est également observée dans les cellules cancéreuses acquérant des propriétés métastatiques. Les événements moléculaires et de nombreux gènes impliqués dans la TEM sont communs au développement de la CN et au cancer.Les liens existant entre le développement de la CN et les neurocristopathies, ainsi que les métastases, soulignent l’importance de l’étude du réseau de régulations génétiques permettant la formation de la CN et l’EMT.Au laboratoire, nous nous intéressons aux événements précoces d’induction et de spécification de la CN. Dans le but d’identifier les gènes préférentiellement impliqués dans le développement précoce de la CN et non dans la formation de l’ectoderme neural et non-neural, un crible a été effectué sur le transcriptome de différents tissus embryonnaires micro-disséqués. La validation des résultats de ce crible a permis d’identifier plusieurs gènes intéressants possédant une fonction potentielle dans la formation de la CN. Nous nous sommes particulièrement intéressés à deux d’entre eux, en raison de leur fonction originale comparée à la majorité des gènes impliqués dans le développement de la CN : serca1 et pfkfb4, un régulateur de l’homéostasie calcique et un régulateur de la glycolyse respectivement.Nous avons analysé les patrons d’expression des gènes des familles serca et pfkfb au cours du développement de Xenopus laevis. En raison de son expression spécifique dans la CN, nous avons étudié plus en détails le rôle de pfkfb4 dans la formation de la CN. Cette analyse a montré que pfkfb4 est nécessaire pour la spécification neurale et de la crête neurale.Toutefois, malgré son rôle documenté dans la glycolyse, le phénotype des morphants pfkfb4 dans l’embryon de Xenopus laevis n’est pas dû à une altération de la glycolyse.En conclusion, nos résultats démontrent l’existence d’un nouveau rôle non glycolytique pour Pfkfb4 au cours du développement embryonnaire de Xenopus Laevis. / Neural Crest (NC) is a transient population of multipotent cells that arises at the border between neural and non-neural ectoderm, in a region named the neural border (NB). As the neural border elevates to form the neural tube, NC cells undergo an Epithelial-To-Mesenchymal Transition (EMT), migrate extensively into the whole body to reach their final destinations and differentiate. They give rise to multiple derivatives: neurons and glia, head cartilage, bones and connective tissue, pigment cells, sympatho-adrenal cells. All these processes are regulated by the concerted actions of several genes that form a complex Gene Regulatory Network (GRN), in which many interactions have been elucidated, but even more relationships still need to be understood. Misregulation of genes normally involved in NC formation causes birth defects called neurocristopathies. Moreover, the EMT that NC cells undergo before migration also takes place when cancer cells become metastatic: the molecular events and many of the genes involved in EMT and migration are shared between NC development and cancer. The links with metastasis, neurocristopathies and the fact that still little is known about the earliest steps of NC formation, highlight the importance and the interest in understanding the Gene Regulatory Network (GRN) leading to NC formation and EMT.In the laboratory, we are interested in the early steps of NC induction and specification. In order to identify genes preferentially involved in early NC development compared to genes involved in neural and non-neural ectoderm formation, a transcriptome screen on different microdissected embryonic tissues has been performed. The validation of the results of the screen revealed several interesting genes with a potential function in NC formation. We focused particularly on two of them, due to their original function compared to the majority of the genes involved in NC development: serca1 and pfkfb4, a calcium homeostasis regulator and a glycolysis regulator respectively. We analysed the expression patterns of serca and pfkfb family genes during Xenopus laevis development. Then, due to its specific expression in NC, we studied more in details the role of pfkfb4 in NC formation. This analysis revealed that pfkfb4 is necessary for neural and neural crest specification. However, despite its known role in glycolysis, pfkfb4 morphant phenotype in Xenopus laevis embryos is not due to an alteration of the glycolytic pathway.In conclusion, our results reveal a novel extra-glycolytic role for Pfkfb4 during Xenopus laevis embryonic development.

Crête Neurale

Xénope

Glycolyse

Pfkfb4

Pfk1

Serca

Métabolisme

Plan d’organisation de l’embryon

Neural Crest

Xenopus

Glycolysis

Pfkfb4

Pfk1

Serca

Metabolism

Embryonic patterning.

Fructose-2, 6-Bisphosphate Associated Regulatory Enzymes Develop in Concordance in Mice Brain During Early Postnatal Life

Pandey, Pankaj, Singh, Sanjay K., Trigun, Surendra K.

07 December 2005

Fructose-2, 6-bisphosphate (fru-2, 6P2), synthesized by 6-phosphofructo-2-kinase (PFK2), regulates glucose metabolism via modulating phosphofructokinase-1 (PFK1) and fructose-1, 6-bisphosphatase (FBPase1) reciprocally in mammalian tissues. How this control system develops in brain is poorly understood. This article presents the postnatal comparative profiles of fru-2, 6P2 and PFK2 & fru-2, 6P2 dependent regulation of PFK1 and FBPase1 in mice brain. Fru-2, 6P2 and PFK2 activity both attained their adult levels in concordance from day1 to 1wk age. Western blot analysis of mice liver and brain & rat liver PFK2 using anti rat liver PFK2/FBPase2 confirmed that both, mice liver and brain isoforms cross- react efficiently with this antibody. In addition, DEAE-eluted brain fractions from different postnatal ages revealed that 1day mice brain expresses a liver type enzyme (∼55 kDa) that is replaced by an adult brain type protein (∼110 kDa) from 1wk onward ages. As compared to 1day mice, significantly decreased Km values of PFK2 at 1wk-10wk ages also suggest the existence of a kinetically different isoform of this enzyme from 1wk onward ages. In vitro effects of fru-2, 6P2 on partially enriched brain PFK1 and FBPase1 suggest that fru-2, 6P2 dependent respective stimulatory and inhibitory responses of both these enzymes increase progressively from day1 to 3wk age. This is well corroborated with the postnatal age-dependent linear increase in PFK1 and decrease in FBPase1 activities in mice brain. The results suggest that fru-2, 6P2 associated regulatory components develop in concordance in mice brain during early postnatal life.

6P 2

FBPase1

Fru-2

PFK1

PFK2

postnatal development

Biomedical Sciences

Developing Brain of Moderately Hypothyroid Mice Shows Adaptive Changes in the Key Enzymes of Glucose Metabolism

Pandey, P., Singh, S. K., Trigun, S. K.

01 December 2005

This study was undertaken to investigate whether the developing brain adapts at biochemical level against neonatal hypothyroidism, as it does so against a variety of physiological disturbances. A moderate hypothyroid state in mice neonates was induced by supplementing 0.05% methimazole in drinking water to the mothers up to suckling period, and its effect on concerted development of the enzymes regulating metabolic channeling of glucose vis a vis glucose phosphorylating activity were studied. In the brain of control mice, the activity of glucose-6-phosphate dehydrogenase (G6PDH), that channels glucose in biosynthetic route (Pentose phosphate pathway, PPP), increased slightly (∼ 1.3 times) from day1 to 10w age. However, glucose phosphorylating activity and the enzymes that commit glucose for energy production, viz phosphofructokinase1 (PFK1), pyruvate kinase (PK) and lactate dehydrogenase (LDH) showed a progressive postnatal increase to attain their respective adult levels (∼ 5-10 times higher than 1day value) by 3-10w ages of mice. In comparison to the control, in the brain of age matched neonatal hypothyroid mice, glucose phosphorylating activity, G6PDH and PFK1 increased significantly (p<0.001) at day1. Thereafter, though, glucose phosphorylating activity continued to increase up to 1w age and remained static thereafter, G6PDH declined significantly (p<0.001) from 1w onward ages. On the other hand, as PFK1 activity increased significantly up to 10w age (p<0.001), the ratio of G6PDH/PFK1 showed a marked decline from 1w onward ages. PK and LDH also showed increasing trend up to 3w age in the brain of hypothyroid mice pups. The results suggest that a moderate hypothyroid state, during the period of rapid brain growth (day 1-1w age), stimulates all the enzymes that regulate channeling of glucose in both, the energy yielding and biosynthetic paths. However, the later postnatal ages, it modulates these enzymes in a metabolic path dependent manner.

brain development

G6PDH

HK

LDH

neonatal hypothyroidism

PFK1

PK

Biomedical Sciences