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NFIX – one gene, two knockouts, multiple effects

Vladimir Pekarik1 and Juan Carlos Izpisua Belmonte12*

Author affiliations

1 Center of Regenerative Medicine in Barcelona, Doctor Aiguader 88, 08003 Barcelona, Spain

2 Salk Institute for Biological Studies, 10010 North Torrey Pines Road, La Jolla, CA 92037, USA

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Citation and License

Journal of Biology 2008, 7:29  doi:10.1186/jbiol94


The electronic version of this article is the complete one and can be found online at: http://jbiol.com/content/7/8/29


Published:23 October 2008

© 2008 BioMed Central Ltd

Abstract

A previous knockout of the transcription factor gene nuclear factor IX (NFIX) in mice produced impaired development of the corpus callosum and severe skeletal defects. A recent paper in BMC Developmental Biology reports an apparently similar NFIX knockout that produced marked differences in phenotype, raising intriguing general questions about the possible causes of such differences in mouse knockouts.

Minireview

The Nuclear Factor I (NFI) family of evolutionarily conserved transcription factors is widely expressed during development and in adulthood, in mammals but has mainly been studied in respect to brain development, where it is intimately associated with glial function [1,2]. The family consists of four members, NFIA, NFIB, NFIC and NFIX, each having multiple splice variants [3]. NFI proteins can directly bind to the promoter and regulate the transcription activity of glial fibrillar acidic protein (GFAP), a marker of glial cells [4]. Different members of the family have been shown to have a variety of roles in neural development but taken together, loss-of-function studies of NFI members in mice reveal a common theme – a lack of development (agenesis) of the corpus callosum, the large tract of nerve fibers interconnecting the left and right hemispheres. The main feature of corpus callosum agenesis is an inability to perform tasks where a matching of visual patterns is required, for example face processing, which in turn results in social difficulties. In mild cases intelligence is mainly unaffected but low muscle tone and motor coordination are affected. In severe cases intellectual retardation, hydrocephalus, seizures and spasticity might be involved. The effect of a mutation varies from partial callosal agenesis (in the case of loss of function of NFIX) to severe agenesis (with loss of function of NFIB having a greater effect than loss of NFIA, as described later).

Less is known so far about the actions of the NFIX gene than about the other members of the family. One known property of NFIX is the regulation of expression of astrocyte-specific α1-antichymotrypsin [5]. To determine the effects of loss of function of NFIX, two groups have recently described knockouts of the NFIX gene [6,7]. Their results turned out to be surprisingly different. The first knockout was reported by a team at the University of Freiburg (Driller et al. [6]) while the second was generated by a group from the University of New York at Buffalo and described in BMC Developmental Biology (Campbell et al. [7]). Here, we briefly review some of the possible reasons for such discrepancies. For simplicity, we will call the mutant strain generated in Freiburg 'X-Freiburg' and the one generated in New York 'X-NY'. Animals of the X-Freiburg strain suffered from hydrocephalus, partial agenesis of the corpus callosum, and spinal deformities that were due to a delay in ossification of vertebral bodies and progressive degeneration of intervertebral discs. Femoral defects were also noticed and animals usually died at around postnatal day (P) 21–28. The X-NY strain, on the other hand, did not suffer from such severe impairments. Callosal agenesis as seen in the X-Freiburg strain was not noted in X-NY NFIX-/- animals. The cingulate cortex and the entire brain are expanded along the dorsal-ventral axis, hippocampus formation is aberrant, and overabundant Pax6- and doublecortin-positive cells are found in the lateral ventricles of X-NY mice.

When the X-NY mice were fed with a soft dough chow they showed a lag in weight gain compared to non-mutant animals, but after P20 the growth rate increased and a few of the animals survived to adulthood. Skeletal deformities observed by Driller et al. and absent in the animals reported by Campbell et al. can be attributed to the severe malnutrition, which was relieved by Campbell et al. by the change in diet. Another possibility is that brain development abnormalities result in reduced appetite, leading again to skeletal defects.

Reconciling the differences

How can the discrepancies reported between the two NFIX-/- strains be reconciled? Among various possible explanations, one could be an alteration of neighboring gene expression. A case in point is the sequential generation of several prion protein (PrP) knockout strains that showed profoundly different phenotypes. Only later was this variation proved to be due to the unintentional activation of another gene in the vicinity of the PrP gene, later named Doppel [8], and which was shown to be neurotoxic.

Both reports of the NFIX knockouts [6,7] describe the deletion of the second exon, which is uniformly present in all splice variants and carries the dimerization and DNA-binding domains (Figure 1). In both cases the targeting constructs were based on a λ phage library derived from the mouse strain 129/Sv, and transgenic animals carrying a single knockout allele were backcrossed to C57BL/6 mice for several generations. However, each research group used a slightly different embryonic stem (ES) cell line for making the mutation. In the case of the X-NY strain the targeting vector was electroporated into J1 ES cells, which are derived from the 129S4/SvJae strain and backcrossed to the C57BL/6 mouse strain for two to five generations. The X-Freiburg targeting construct was electroporated into CJ7 ES cells, which originate from the 129S1/Sv strain (129S1/Sv-p+Tyr+KitlSl-J) and transgenic animals were backcrossed to C57BL/6. Driller et al. [6] do not specify the number of backcrossings to C57BL/6, which raises the possibility that their knockout strains, although apparently congenic with those of Campbell et al., contain a substantial segment of ES-cell-derived chromosome still flanking the knockout allele – a 'congenic footprint'.

thumbnailFigure 1. For simplicity the same structure is drawn for all four NFI genes. (a) The organization of the NFI genes. They can all use an alternative exon 1, here denoted as a single box labeled 1a/1b. The DNA-binding and dimerization domains are located in exon 2. (b) In general, two approaches are used for knockouts of these genes. The first relies on complete deletion of the second exon (including 5' and 3' splice acceptor sites of proximal introns), as shown here in the X-NY knockout. The second strategy is to insert LacZ (or a LacZ-neo hybrid or PGK-neo hybrid) in-frame into the second exon, leading to production of a fusion protein composed of a few amino acids derived from exons 1 and 2 of the NFI and LacZ genes. In all cases an alternative splice variant joining the first and the third exon of the NFI gene will be formed. The third exon is not in frame with the first, and so premature termination of translation will occur. Whether a peptide produced from the joining of exons 1 and 3 has any physiological function was never analyzed, but judging from the very different phenotypes of the different knockout strains it seems rather unlikely. The NFIB constructs are reported in [15,16], the NFIA knockout in [17] and the NFIC knockout in [18].

In a study of congenic knockouts at another gene, Schalkwyk et al. [9] found that at least 10 genes across 40 Mb around the targeted locus show differences in expression in the different knockout strains, due to the congenic footprint effect. Genome-wide analysis of gene expression in different tissues of knockout animals by microarray profiling also indicates that a significant proportion of changes are found in the proximity of the targeted gene [10,11]. This little excursion into the theory of induced mutation experiments does not seem so trivial in the light of several studies describing corpus callosum defects in the 129/Sv strain itself [12,13], which vary between 129 substrains studied [14]. Callosal agenesis is one of the phenotypic features ascribed to the X-Freiburg strain, while at the same time complete callosal agenesis was not seen in X-NY strain. The locus (or loci) responsible for callosal agenesis in the 129/Sv strain is not characterized and it is not unreasonable to speculate that such a region might be present in the proximity of NFIX in the X-Freiburg strain, whereas in the X-NY strain this locus had been removed by outbreeding.

Another possible source of variation emanates from the targeting strategy used. Campbell et al. completely deleted the second exon along with proximal parts of neighboring introns, whereas Driller et al. replaced the second exon with a coding sequence of the LacZ gene fused to a coding sequence of NFIX (Figure 1b). In this regard, a comparison of all the available NFI gene knockouts is perhaps more informative (Figure 1b). An intriguing feature that emerges from this comparison is that mice in which the 3' splice acceptor of the first intron is removed somehow have a milder phenotype. Without further experimental evidence it is difficult to explain this observation, which could be purely coincidental. Formation of an alternatively spliced gene variant (which was not looked for), as with the activation of Doppel [8], is one possibility. Alternatively, the fusion of the first few amino acids of NFIX (or NFIB) to LacZ might lead to a toxic gain-of-function protein. The peptide in question is quite short but even so could endow the fusion protein with toxic properties. This hypothesis is rather easy to test by overexpressing recombinant NFIXexon1-LacZ protein in glial or neuronal cells.

A full explanation of these intriguing phenotypes will require experimental testing and a proper analysis of the ideas put forward here, as well as other possibilities. Thorough analysis of all available knockouts might reveal surprising new functions of NFI proteins and further enhance our understanding of their biological functions.

Acknowledgements

Work in the laboratory of Juan Carlos Izpisua Belmonte was supported by funds from the G Harold and Leila Y Mathers Charitable Foundation, Fundacion Cellex and the Marato.

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