Josée Aubin

Sustained Hox5 Gene Activity is Required for Respiratory Motor Neuron Development

Respiration in mammals relies on the rhythmic firing of neurons in the phrenic motor column (PMC), a motor neuron group that provides the sole source of diaphragm innervation. Despite their essential role in breathing, the specific determinants of PMC identity and patterns of connectivity are largely unknown. We show that two Hox genes, Hoxa5 and Hoxc5, control diverse aspects of PMC development including their clustering, intramuscular branching, and survival. In mice lacking Hox5 genes in motor neurons, axons extend to the diaphragm, but fail to arborize, leading to respiratory failure. Genetic rescue of cell death fails to restore columnar organization and branching patterns, indicating these defects are independent of neuronal loss. Unexpectedly, late Hox5 removal preserves columnar organization but depletes PMC number and branches, demonstrating a continuous requirement for Hox function in motor neurons. These findings indicate that Hox5 genes orchestrate PMC development through deployment of temporally distinct wiring programs.

TRANSCRIPTIONAL INTERFERENCES AT THE HOXA4/HOXA5 LOCUS : IMPORTANCE OF CORRECT HOXA5 EXPRESSION FOR THE PROPER SPECIFICATION OF THE AXIAL SKELETON

We have previously described a Hoxa5 mutant mouse line in which specification of axial identity is perturbed and viability is markedly reduced. In the present study, we assay the Hoxa5 mutation in different genetic backgrounds and carry out a complete analysis of skeletal transformations. Although Hoxa5is expressed over a large domain during embryogenesis, homeotic transformations of the axial skeleton are confined between cervical vertebra C3 and thoracic vertebra T2, which corresponds to the specific expression domain of the major Hoxa5 transcript. Loss of Hoxa5 function also affects the formation of the acromion in the appendicular skeleton. Disruption of the adjacent Hoxa4 gene leads to similar homeotic transformations of the cervicothoracic vertebrae. To discriminate the respective role ofeachgene, we generated transheterozygous animals carrying inactivated Hoxa4 and Hoxa5 alleles on different chromosomes. Compound heterozygous mutants exhibit homeotic transformations in the cervicothoracic transition region more reminiscent to those observed in Hoxa5 homozygous mutants. Although the Hoxa5 mutation does not significantly affect Hoxa4 expression, the pattern of Hoxa5 expression is impaired in cis by the Hoxa4 mutation, specifically<0B> <0R>in the cervicothoracic region of the prevertebral column. The expression of Hoxa5 in this particular domain is also perturbed by the Hoxa5 mutation itself, raising the possibility of regional autoregulation. Altogether, these results demonstrate the crucial role of Hoxa5 in the specification of the cervical and upper thoracic region of the skeleton and establish the importance of its correct expression for the proper patterning of the embryo. Dev. Dyn. 1998;212:141–156.

Loss of Hoxa5 gene function in mice perturbs intestinal maturation

The Hox gene family of transcription factors constitutes candidate regulators in the molecular cascade of events that governs establishment of normal terminal differentiation along the duodenum to colon axis. One member of this family, Hoxa5, displays a dynamic pattern of expression during gut development. Hoxa5 transcripts are present in midgut mesenchyme at the time of remodeling, supporting a role for this gene in digestive tract specification. To study the role of Hoxa5 in proper intestinal development and maturation, we examined whether Hoxa5 mutant mice exhibit any defect in this process. We report here that even though Hoxa5 is not required for midgut morphogenesis, its loss of function perturbs the acquisition of adult mode of digestion, which normally is temporally coordinated with the process of spontaneous weaning. Impaired maturation of the digestive tract might be related to altered specification of intestinal epithelial cells. Our findings provide evidence that Hoxa5 expression in the gut mesoderm is important for the region-specific differentiation of the adjacent endoderm.

Perturbed thyroid morphology and transient hypothyroidism symptoms in Hoxa5 mutant mice

The Hox family of transcriptional regulators has been extensively studied for their role in axial and appendicular patterning. Genetic analyses have also unveiled Hox gene function in organogenesis and postnatal development. A phenotypical survey of the Hoxa5−/− mutant mice shows that the surviving mutants display symptoms of hypothyroidism, including transient growth retardation, and delayed eye opening and ear elevation. Thyroid gland morphogenesis initiates normally, but follicle formation and thyroglobulin processing are abnormal at late gestation. The expression of several molecular markers essential for thyroid gland formation and function, namely Nkx2.1, Pax8, and Titf2, is affected in the developing thyroid gland of Hoxa5−/− mutants. As a consequence, the expression of thyroid effector genes, including the thyroglobulin and thyroperoxidase genes, is perturbed. Our characterization reveals that the loss of Hoxa5 function transiently affects thyroid development in a non–cell autonomous manner. Developmental Dynamics 227:367–378, 2003.

Multiple cis-acting regulatory regions are required for restricted spatio-temporal Hoxa5 gene expression.

Genetic analyses have revealed the essential role of the murine Hoxa5 gene for the correct specification of the cervical and upper thoracic region of the skeleton, and for the normal organogenesis and function of the respiratory tract, both structures expressing Hoxa5 during embryogenesis. To understand how the expression domains of the Hoxa5 gene are established during development, we have analyzed the cis‐acting control regions mediating Hoxa5 gene expression using a transgenic approach. Four transcripts are derived from the Hoxa5 locus. The shortest and most abundant one displays a specific spatio‐temporal profile of expression at earlier stages and in more anterior structures along the embryonic axis than the larger forms. We established that an 11.1 kilobase pair (kb) genomic fragment, extending from position −3.8 kb to +7.3 kb relative to Hoxa5 transcription initiation site, was sufficient to reproduce the temporal expression and substantially reconstitute the spatial pattern of the major Hoxa5 transcript. By deletion analyses, we identified a 2.1 kb fragment located downstream of the Hoxa5 gene that possesses mesodermal enhancer activity. Overall, the findings demonstrate that cis‐acting regulatory elements essential for the correct expression of the major Hoxa5 transcript are located both upstream and downstream of the Hoxa5 coding sequences. Dev Dyn 1999;214:127–140. 

Partial functional redundancy between Hoxa5 and Hoxb5 paralog genes during lung morphogenesis

Hox genes encode transcription factors governing complex developmental processes in several organs. A subset of Hox genes are expressed in the developing lung. Except for Hoxa5, the lack of overt lung phenotype in single mutants suggests that Hox genes may not play a predominant role in lung ontogeny or that functional redundancy may mask anomalies. In the Hox5 paralog group, both Hoxa5 and Hoxb5 genes are expressed in the lung mesenchyme whereas Hoxa5 is also expressed in the tracheal mesenchyme. Herein, we generated Hoxa5;Hoxb5 compound mutant mice to evaluate the relative contribution of each gene to lung development. Hoxa5;Hoxb5 mutants carrying the four mutated alleles displayed an aggravated lung phenotype, resulting in the death of the mutant pups at birth. Characterization of the phenotype highlighted the role of Hoxb5 in lung formation, the latter being involved in branching morphogenesis, goblet cell specification, and postnatal air space structure, revealing partial functional redundancy with Hoxa5. However, the Hoxb5 lung phenotypes were less severe than those seen in Hoxa5 mutants, likely because of Hoxa5 compensation. New specific roles for Hoxa5 were also unveiled, demonstrating the extensive contribution of Hoxa5 to the developing respiratory system. The exclusive expression of Hoxa5 in the trachea and the phrenic motor column likely underlies the Hoxa5-specific trachea and diaphragm phenotypes. Altogether, our observations establish that the Hoxa5 and Hoxb5 paralog genes shared some functions during lung morphogenesis, Hoxa5 playing a predominant role.

Multiple Promoters and Alternative Splicing: Hoxa5 Transcriptional Complexity in the Mouse Embryo

Background The genomic organization of Hox clusters is fundamental for the precise spatio-temporal regulation and the function of each Hox gene, and hence for correct embryo patterning. Multiple overlapping transcriptional units exist at the Hoxa5 locus reflecting the complexity of Hox clustering: a major form of 1.8 kb corresponding to the two characterized exons of the gene and polyadenylated RNA species of 5.0, 9.5 and 11.0 kb. This transcriptional intricacy raises the question of the involvement of the larger transcripts in Hox function and regulation. Methodology/Principal Findings We have undertaken the molecular characterization of the Hoxa5 larger transcripts. They initiate from two highly conserved distal promoters, one corresponding to the putative Hoxa6 promoter, and a second located nearby Hoxa7. Alternative splicing is also involved in the generation of the different transcripts. No functional polyadenylation sequence was found at the Hoxa6 locus and all larger transcripts use the polyadenylation site of the Hoxa5 gene. Some larger transcripts are potential Hoxa6/Hoxa5 bicistronic units. However, even though all transcripts could produce the genuine 270 a.a. HOXA5 protein, only the 1.8 kb form is translated into the protein, indicative of its essential role in Hoxa5 gene function. The Hoxa6 mutation disrupts the larger transcripts without major phenotypic impact on axial specification in their expression domain. However, Hoxa5-like skeletal anomalies are observed in Hoxa6 mutants and these defects can be explained by the loss of expression of the 1.8 kb transcript. Our data raise the possibility that the larger transcripts may be involved in Hoxa5 gene regulation. Significance Our observation that the Hoxa5 larger transcripts possess a developmentally-regulated expression combined to the increasing sum of data on the role of long noncoding RNAs in transcriptional regulation suggest that the Hoxa5 larger transcripts may participate in the control of Hox gene expression.

Functional resolution of duplicated hoxb5 genes in teleosts.

The duplication-degeneration-complementation (DDC) model predicts that subfunctionalization of duplicated genes is a common mechanism for their preservation. The additional Hox complexes of teleost fish constitute a good system in which to test this hypothesis. Zebrafish have two hoxb complexes, with two hoxb5 genes, hoxb5a and hoxb5b, the expression patterns of which suggest subfunctionalization of an ancestral hoxb5 gene. We characterized conserved non-coding elements (CNEs) near the zebrafish hoxb5 genes. One CNE, J3, is only retained in the hoxb5a locus, whereas the others, J1 and J2, are present in both hoxb5 loci. When tested individually, the enhancer activity of individual CNEs, including J3, extensively overlapped and did not support a role in subfunctionalization. By contrast, reporter transgene constructs encompassing multiple CNEs were able to target reporter gene expression to unique domains of hoxb5a and hoxb5b expression. The deletion of J3 from the hoxb5a locus resulted in expression that approached that of hoxb5b, whereas its insertion in the hoxb5b locus increased reporter expression and rendered it more similar to that of hoxb5a. Our results highlight the importance of interactions between CNEs in the execution of complementary subfunctions of duplicated genes.

Unsuspected effects of a lung-specific Cre deleter mouse line.

Cre‐expressing mouse lines constitute an important asset to mammalian genetics, allowing the deletion of genes in a spatio‐temporal specific manner. Our study on Hox gene function in lung development has led us to use a lung endoderm‐specific deletion with the Sftpc‐cre mouse line expressing the Cre recombinase gene under the control of human surfactant protein C regulatory sequences. In control experiments, the Cre recombinase faithfully activated the Rosa26‐lacZ reporter gene in lung epithelium. However as early as e15.5, lungs from Sftp‐Cre+ embryos showed abnormal dilated cysts. This unexpected phenotype was also observed in mice carrying the conditional lung epithelial Hoxa5 deletion, indicating some bias due to Cre deleterious effects. Excessive apoptosis, likely due to Cre toxicity, could explain the abnormal cysts. Our findings illustrate the need for appropriate control experiments and careful interpretation of data to discriminate between the phenotype due to the targeted mutation and the confounding effects of the Cre recombinase. genesis 49:152‐159, 2011.

Influence of Hoxa5 on p53 Tumorigenic Outcome in Mice

Hox genes encode transcription factors of crucial importance in the pattern formation of a large spectrum of species. Several studies have now proposed a role for these developmental genes in cancer biology. It has been suggested that HOXA5 possesses growth-suppressive properties through activation of p53 expression in human breast tissue. To assess the genetic cooperation that may exist between Hoxa5 and p53 in tumorigenesis, we generated Hoxa5/p53 compound mutant mice. The presence of Hoxa5 null alleles increased the susceptibility of p53(-/-) mice to develop tumors with a high prevalence for thymic lymphoma, suggesting that the loss of function of the two genes collaborate in tumor formation. To extend our analysis to mammary tumorigenesis, we performed Hoxa5/p53 whole mammary gland transplantations into wild-type hosts. In the p53(-/-) background, the presence of one Hoxa5 mutant allele had no impact on mammary tumor formation. In contrast, the complete loss of Hoxa5 function influenced the tumorigenic outcome of p53(+/-) mammary glands. However, the collaborative nature of this interaction did not depend on the transcriptional regulation of p53 by Hoxa5. Altogether, our data establish that Hoxa5 and p53 cooperate in mammary tumorigenesis in vivo.