A role for neural determination genes in specifying the dorsoventral identity of telencephalic neurons.

Neurogenin1 (Ngn1), Neurogenin2 (Ngn2), and Mash1 encode bHLH transcription factors with neuronal determination functions. In the telencephalon, the Ngns and Mash1 are expressed at high levels in complementary dorsal and ventral domains, respectively. We found that Ngn function is required to maintain these two separate expression domains, as Mash1 expression is up-regulated in the dorsal telencephalon of Ngn mutant embryos. We have taken advantage of the replacement of the Ngns by Mash1 in dorsal progenitors to address the role of the neural determination genes in neuronal-type specification in the telencephalon. In Ngn2 single and Ngn1; Ngn2 double mutants, a population of early born cortical neurons lose expression of dorsal-specific markers and ectopically express a subset of ventral telencephalic-specific markers. Analysis of Mash1; Ngn2 double mutant embryos and of embryos carrying a Ngn2 to Mash1 replacement mutation demonstrated that ectopic expression of Mash1 is required and sufficient to confer these ventral characteristics to cortical neurons. Our results indicate that in addition to acting as neuronal determinants, Mash1 and Ngns play a role in the specification of dorsal-ventral neuronal identity, directly linking pathways of neurogenesis and regional patterning in the forebrain.

Sak kinase gene structure and transcriptional regulation.

The Sak gene encodes a serine/threonine kinase, which is a member of the Polo family of mitotic regulators. Sak transcripts are present in S/G2/M phase cells, and in proliferating cell layers of the mouse embryo and adult tissues. In this report, we have characterized the murine Sak gene structure, the Sak chromosomal location, and identified the promoter. The murine Sak gene is located on the proximal arm of mouse chromosome 13, as determined by RFLP analysis. The murine gene comprises 15 coding exons spanning 16kb of genomic sequence, and encodes two alternately spliced transcripts. Sak-a, the predominant transcript, is encoded by 15 exons, while early termination of transcription and alternative splicing at exons 5 and 6 results in Sak-b. This truncated transcript encodes the complete kinase domain and a carboxyl end translated from 147bp of sequence contiguous with exon 5. Human Sak-a (Stk18) cDNA is reported to contain an insertion of sequence corresponding to the mouse Sak-b tail. Primer extension analysis of murine Sak revealed one major transcription start site at position -303bp relative to the start of translation. A genomic fragment of 3.5kb located 5' of the Sak transcriptional start drives expression of a luciferase-reporter gene in CHO and GC1-SPG cells in an orientation-dependent fashion. Using various Sak promoter/luciferase constructs, the core promoter region required for expression was located within 400bp of the message Cap site, and sequence further 5' strongly suppressed transcription.

Neurogenin1 and neurogenin2 control two distinct waves of neurogenesis in developing dorsal root ganglia.

Different classes of sensory neurons in dorsal root ganglia (DRG) are generated in two waves: large-diameter trkC+ and trkB+ neurons are born first, followed by small-diameter trkA+ neurons. All such neurons require either neurogenin (ngn) 1 or 2, two neuronal determination genes encoding basic helix-loop-helix (bHLH) transcription factors. ngn2 is required primarily if not exclusively for the generation of trkC+ and trkB+ neurons, whereas the generation of most or all trkA+ neurons requires ngn1. Comparison with previous lineage tracing data in the chick suggests that this dichotomy reflects a requirement for the two ngns in distinct sensory precursor populations. The neurogenesis defect in ngn2(-/-) embryos is transient and later compensated by ngn1-dependent precursors, suggesting that feedback or competitive interactions between these precursors may control the proportion of different neuronal subtypes they normally produce. These data reveal remarkable parallels in the roles of bHLH factors during neurogenesis in the DRG, and myogenesis in the neighboring myotome.

Mash1 regulates neurogenesis in the ventral telencephalon.

Previous studies have shown that mice mutant for the gene Mash1 display severe neuronal losses in the olfactory epithelium and ganglia of the autonomic nervous system, demonstrating a role for Mash1 in development of neuronal lineages in the peripheral nervous system. Here, we have begun to analyse Mash1 function in the central nervous system, focusing our studies on the ventral telencephalon where it is expressed at high levels during neurogenesis. Mash1 mutant mice present a severe loss of progenitors, particularly of neuronal precursors in the subventricular zone of the medial ganglionic eminence. Discrete neuronal populations of the basal ganglia and cerebral cortex are subsequently missing. An analysis of candidate effectors of Mash1 function revealed that the Notch ligands Dll1 and Dll3, and the target of Notch signaling Hes5, fail to be expressed in Mash1 mutant ventral telencephalon. In the lateral ganglionic eminence, loss of Notch signaling activity correlates with premature expression of a number of subventricular zone markers by ventricular zone cells. Therefore, Mash1 is an important regulator of neurogenesis in the ventral telencephalon, where it is required both to specify neuronal precursors and to control the timing of their production.

The bHLH protein NEUROGENIN 2 is a determination factor for epibranchial placode-derived sensory neurons.

neurogenin2 encodes a neural-specific basic helix-loop-helix (bHLH) transcription factor related to the Drosophila proneural factor atonal. We show here that the murine ngn2 gene is essential for development of the epibranchial placode-derived cranial sensory ganglia. An ngn2 null mutation blocks the delamination of neuronal precursors from the placodes, the first morphological sign of differentiation in these lineages. Mutant placodal cells fail to express downstream bHLH differentiation factors and the Notch ligand Delta-like 1. These data suggest that ngn2 functions like the Drosophila proneural genes in the determination of neuronal fate in distal cranial ganglia. Interestingly, the homeobox gene Phox2a is activated independently of ngn2 in epibranchial placodes, suggesting that neuronal fate and neuronal subtype identity may be specified independently in cranial sensory ganglia.

Mash1 activates a cascade of bHLH regulators in olfactory neuron progenitors.

The lineage of olfactory neurons has been relatively well characterized at the cellular level, but the genes that regulate the proliferation and differentiation of their progenitors are currently unknown. In this study, we report the isolation of a novel murine gene, Math4C/neurogenin1, which is distantly related to the Drosophila proneural gene atonal. We show that Math4C/neurogenin1 and the basic helix-loop-helix gene Mash1 are expressed in the olfactory epithelium by different dividing progenitor populations, while another basic helix-loop-helix gene, NeuroD, is expressed at the onset of neuronal differentiation. These expression patterns suggest that each gene marks a distinct stage of olfactory neuron progenitor development, in the following sequence: Mash1>Math4C/neurogenin1>NeuroD. We have previously reported that inactivation of Mash1 function leads to a severe reduction in the number of olfactory neurons. We show here that most cells in the olfactory epithelium of Mash1 mutant embryos fail to express Math4C/neurogenin1 or NeuroD. Strikingly, a subset of progenitor cells in a ventrocaudal domain of Mash1 mutant olfactory epithelium still express Math4C/neurogenin1 and NeuroD and differentiate into neurons. Cells in this domain also express Math4A/neurogenin2, another member of the Math4/neurogenin gene family, and not Mash1. Our results demonstrate that Mash1 is required at an early stage in the olfactory neuron lineage to initiate a differentiation program involving Math4C/neurogenin1 and NeuroD. Another gene activates a similar program in a separate population of olfactory neuron progenitors.

Restricted expression of a novel murine atonal-related bHLH protein in undifferentiated neural precursors.

Tissue-specific bHLH proteins play important roles in the specification and differentiation of neural cell lineages in invertebrate and vertebrate organisms. Two groups of bHLH proteins, atonal and achaete-scute, have proneural activities in Drosophila, and the mouse achaete-scute homolog MASH1 is required for the differentiation of several neural lineages. In a screen for proteins interacting with MASH1, we have isolated a novel bHLH protein related to atonal, named MATH4A, which is broadly expressed in neural precursor cells in the mouse embryonic CNS and PNS. Interaction assays in yeast and in vitro demonstrate that MATH4A interacts efficiently with both MASH1 and the ubiquitous bHLH protein E12. MATH4A-E12 heterodimers, but not MATH4A-MASH1, bind to a consensus E-box sequence. Math4A expression is restricted to undifferentiated neural precursors and is complementary to that of Mash1 in most regions of the nervous system. In particular, Math4A is transcribed at high levels in the cerebral cortex, dorsal thalamus, and epibranchial placodes, which present little or no Mash1 expression. However, expression of the two genes shows limited overlap in certain CNS regions (retina, preoptic area of the hypothalamus, midbrain, hindbrain). Its structure and expression pattern suggest that MATH4A may regulate an early step of neural development, either as a partner of ubiquitous bHLH proteins or associated with other neural-specific bHLH proteins.

Constitutive expression of murine Sak-a suppresses cell growth and induces multinucleation.

The murine Sak gene encodes two isoforms of a putative serine/threonine kinase, Sak-a and Sak-b, with a common N-terminal kinase domain and different C-terminal sequences. Sak is expressed primarily at sites where cell division is most active in adult and embryonic tissues (C. Fode, B. Motro, S. Youseli, M. Heffernan, and J. W. Dennis, Proc. Natl. Acad. Sci. USA 91:6388-6392, 1994). In this study, we found that Sak-a transcripts were absent in growth-arrested NIH 3T3 cells, while in cycling cells, mRNA levels increased late in G1 phase and remained elevated through S phase and mitosis before declining early in G1. The half-life of hemagglutinin epitope-tagged Sak-a protein was determined to be approximately 2 to 3 h, and the protein was observed to be multiubiquitinated, a signal for rapid protein degradation. Overexpression of Sak-a protein inhibited colony-forming efficiency in CHO cells. Neither the Sak-b isoform nor Sak-a with a mutation in a strictly conserved residue in the kinase domain (Asp-154-->Asn) conferred growth inhibition, suggesting that both the kinase domain and the C-terminal portion of Sak-a are functional regions of the protein. Sak-a overexpression did not induce a block in the cell cycle. However, expression of HA-Sak-a, but not HA-Sak-b, from a constitutive promoter for 48 h in CHO cells increased the incidence of multinucleated cells. Our results show that Sak-a transcript levels are controlled in a cell cycle-dependent manner and that this precise regulation is necessary for cell growth and the maintenance of nuclear integrity during cell division.

GlcNAc-transferase V and core 2 GlcNAc-transferase expression in the developing mouse embryo.

UDP-GlcNAc:Manalpha1-6Manbeta-R beta1-6-N-acetylglucosaminyltransferase V (GlcNAc-TV) and UDP-GlcNAc:Galbeta1-3GalNAc-R beta1-6-N-acetylglucosaminyltransferase (core 2 GlcNAc-T) are Golgi enzymes that catalyse the biosynthesis of beta1-6GlcNAc-branched intermediates in the N- and O-linked biosynthesis pathways, respectively. The activities of these enzymes change during haematopoiesis, embryo-carcinoma cell differentiation and following malignant transformation, but little is known about their expression in normal adult tissues and during embryogenesis. We have examined the expression of GlcNAc-TV and core 2 GlcNAc-T in sections of post-implantation mouse embryos by in situ RNA hybridization. The two enzymes showed distinct temporal and spatial patterns of expression. Core 2 GlcNAc-T mRNA was widely expressed at embryonic day (E) 7, and became restricted to a subset of mucin- and cartilage-producing tissues at E11.5 through to E17.5. GlcNAc-TV transcripts were absent at E7, became expressed throughout E9.5 embryos, and then progressively restricted to regions of the developing central nervous system and to specialized epithelia of skin, intestine, kidney, endocrine tissues and respiratory tract. In the adult gonads, GlcNAc-TV transcripts were excluded from germ cells, but were detected in the follicular and testicular cells. Leukoagglutinin (L-PHA)-reactive oligosaccharides co-localized with GlcNAc-TV transcripts in skin, kidney and intestine, but brain showed unexpectedly low overall staining punctuated by bright staining of the vascular endothelium. A common feature of cells in basal epithelia and in the cortical neural epithelium is the capacity to migrate, a cellular function which may require GlcNAc-TV-dependent glycoconjugates.

Sak, a murine protein-serine/threonine kinase that is related to the Drosophila polo kinase and involved in cell proliferation.

We have isolated murine cDNAs encoding two isoforms of a putative protein-serine/threonine kinase, designated Sak-a and Sak-b, which differ in their noncatalytic C-terminal ends. The kinase domain of Sak is related to the catalytic domains of the Drosophila polo, Saccharomyces cerevisiae CDC5, and murine Snk and Plk kinases, a family of proteins for which a role in controlling cell proliferation has been established (polo, CDC5) or implicated (Snk, Plk). Northern and in situ RNA analyses of Sak gene expression in mouse embryos and adult tissues revealed that expression was associated with mitotic and meiotic cell division. In addition, during embryogenesis, Sak expression was prominent in the respiratory and olfactory mucosa. The pattern of Sak expression and its sequence homology with the polo gene family suggest that the Sak kinase may play a role in cell proliferation. In support of this, cell growth was suppressed by expression of a Sak-a-antisense fragment in CHO cells.