Rhox homeobox gene cluster: recent duplication of three family members

We recently reported the discovery of a homeobox gene cluster on the mouse X chromosome, Rhox, whose 12 members are selectively expressed in specific cell types in reproductive organs. Here we report the existence of 20 additional Rhox homeobox genes in this gene cluster. Most of the newly identified Rhox paralogs retain the same order and relative orientation as three of the originally described Rhox genes, suggesting that they arose from recent duplications of this trimer unit. Many of these new Rhox family members are expressed in the testis and placenta. Analysis of synonymous and nonsynonymous substitutions in their homeodomain region suggests that these new Rhox paralogs duplicated so recently that their encoded proteins have not yet acquired distinct DNA-binding specificities. The existence of these new Rhox genes provides an opportunity to examine the initial stages of gene cluster evolution.     

Remarkable expansions of an X-linked reproductive homeobox gene cluster in rodent evolution

Rhox is a recently identified cluster of 12 X-linked homeobox genes in mice. The expression pattern of Rhox genes during postnatal testis development corresponds to their chromosomal position, much like the colinear gene regulation of the Hox gene clusters during animal embryonic development. We here report the identification of 18 additional Rhox genes and 3 pseudogenes in mice. Comparative analyses of the mouse, rat, human, dog, cow, opossum, and chicken genomes suggest that the Rhox cluster originated in the common ancestor of primates and rodents. It subsequently underwent two remarkable expansions, first in the common ancestor of mice and rats and then in mice. Positive selection promoting amino acid substitutions was detected in some young Rhox genes, suggesting adaptive functional diversification. The recent expansions of the Rhox cluster provide an opportunity to study the mechanism and origin of colinear gene regulation, but they may also undermine the utility of mouse models for understanding the development and physiology of the human reproductive system.     

The rhox homeobox gene family shows sexually dimorphic and dynamic expression during mouse embryonic gonad development

Reproductive capacity is fundamental to the survival of all species. Consequently, much research has been undertaken to better understand gametogenesis and the interplay between germ cells and the somatic cell lineages of the gonads. In this study, we have analyzed the embryonic expression pattern of the X-linked gene family Reproductive homeobox genes on the X chromosome (Rhox) in mice. Our data show that eight members of the Rhox gene family are developmentally regulated in sexually dimorphic and temporally dynamic patterns in the developing germ cells during early gonadogenesis. These changes coincide with critical stages of differentiation where the germ cells enter either mitotic arrest in the testis or meiotic arrest in the ovary. Finally, we show that Rhox8 (Tox) is the only member of the Rhox gene family that is expressed in the somatic compartment of the embryonic gonads. Our results indicate that the regulation of Rhox gene expression and its potential function during embryogenesis are quite distinct from those previously reported for Rhox gene regulation in postnatal gonads.     

Mdfic与Rhox5蛋白相互作用的关键结构域鉴定

Mdfic（MyoD family inhibitor domain containing）是一个新发现的含有MyoD抑制素结构域（I-mfa domain）的转录调控因子,可能在肌细胞的分化过程中发挥重要作用. 小鼠Rhox5为同源异型框基因,隶属于Rhox基因簇（reproductive homeobox on the X chromosome genes cluster）β亚簇.在前期证实Mdifc能结合Rhox5蛋白的基础上,进一步鉴定两者相互作用的关键结构域.生物信息学分析Mdfic 的氨基酸序列,PCR方法扩增Mdfic A截短型片段（第72～247位氨基酸残基）,含保守的I-mfa结构域; 双向酵母双杂交和体外GST-Pull down结果表明,该截短型片段可以与Rhox5蛋白结合,且结合力度较完整的Mdfic蛋白强; 将Mdfic A片段划分为两段: Mdfic B（72～191 aa, 不含I-mfa结构域）和Mdfic C（191～247 aa, 含I-mfa结构域）.结果表明,含保守I-mfa结构域的Mdfic C截短型片段丧失了与Rhox5蛋白结合的能力,而不含I-mfa结构域的Mdfic B截短型片段可以结合Rhox5蛋白. 鉴于Mdfic蛋白的非I-mfa结构域在Rhox5/Mdfic结合中发挥关键作用, Rhox5与Mdfic的结合可能进一步调控由Mdfic的I-mfa结构域参与的其他转录因子（如MyoD）的调控,三者形成一个复杂的调控网络,共同参与肌细胞发生及分化的调控.     

High-level expression, polyclonal antibody preparation and sub-cellular localization analysis of mouse Rhox5 protein

Mouse reproductive homeobox on the X chromosome (Rhox) is a novel homeobox gene cluster. Rhox5, also called Pem, belongs to the beta subcluster of Rhox. Codon analysis indicated that the cDNA contains 16% of codons rarely used in Escherichia coli. To achieve high-level expression of Rhox5, the coding sequence of Rhox5 was amplified and subcloned into the prokaryotic expression vector pET22b (+) in order to produce 6His-tagged fusion protein in the modified BL21 (DE3) cells, namely Rosetta2 (DE3) cells. The 6His-tagged Rhox5 was expressed efficiently in Rosetta2 (DE3), compared with marginal expression in BL21 (DE3). The fusion protein amounted to 16% of the total bacterial proteins after induction with 0.4mM IPTG for 1.5h at 37 degrees C. After purification, Rhox5-6His was used to immunize New Zealand white rabbits following standard protocol. The homemade antiserum could detect both endogenous Rhox5 protein expressed in eukaryotic cells (Cos-7) and exogenous GFP-Rhox5 protein. Furthermore, the antiserum was used to determine the localization of Rhox5 in NIH3T3 cells using an immunofluorescence technique. The results demonstrated that Rhox5 was localized predominantly in the nucleus. Preparation of the anti-Rhox5 polyclonal antibody will facilitate further functional study of Rhox5.     

The Rhox5 homeobox gene regulates the region-specific expression of its paralogs in the rodent epididymis

The mechanisms by which the region-specific expression patterns of clustered genes evolve are poorly understood. The epididymis is an ideal organ to examine this, as it is a highly segmented tissue that differs significantly in structure between closely related species. Here we examined this issue through analysis of the rapidly evolving X-linked reproductive homeobox (Rhox) gene cluster, the largest known homeobox gene cluster in metazoans. In the mouse, we found that most Rhox genes are expressed primarily in the caput region of the epididymis, a site where sperm mature and begin acquiring forward motility. This region-specific expression pattern depends, in part, on the founding member of the Rhox cluster--Rhox5--as targeted mutation of Rhox5 greatly diminishes the expression of several other family members in the caput region. In the rat, Rhox5 expression switches from the caput to the site of sperm storage: the cauda. All Rhox genes under the control of Rhox5 in the mouse epididymis display a concomitant change in their regional expression in the rat epididymis. Our results lead us to propose that widespread changes in the region-specific expression pattern of genes over evolutionary time can be the result of alterations of one or only a few master regulatory genes.     

Comparison of gene expression in male and female mouse blastocysts revealed imprinting of the X-linked gene, Rhox5/Pem, at preimplantation stages

Mammalian male preimplantation embryos develop more quickly than females . Using enhanced green fluorescent protein (EGFP)-tagged X chromosomes to identify the sex of the embryos, we compared gene expression patterns between male and female mouse blastocysts by DNA microarray. We detected nearly 600 genes with statistically significant sex-linked expression; most differed by 2-fold or less. Of 11 genes showing greater than 2.5-fold differences, four were expressed exclusively or nearly exclusively sex dependently. Two genes (Dby and Eif2s3y) were mapped to the Y chromosome and were expressed in male blastocysts. The remaining two (Rhox5/Pem and Xist) were mapped to the X chromosome and were predominantly expressed in female blastocysts. Moreover, Rhox5/Pem was expressed predominantly from the paternally inherited X chromosome, indicating sex differences in early epigenetic gene regulation.     

Germ cell development in the XXY mouse: evidence that X chromosome reactivation is independent of sexual differentiation

Prior to entry into meiosis, XX germ cells in the fetal ovary undergo X chromosome reactivation. The signal for reactivation is thought to emanate from the genital ridge, but it is unclear whether it is specific to the developing ovary. To determine whether the signals are present in the developing testis as well as the ovary, we examined the expression of X-linked genes in germ cells from XXY male mice. To facilitate this analysis, we generated XXY and XX fetuses carrying X chromosomes that were differentially marked and subject to nonrandom inactivation. This pattern of nonrandom inactivation was maintained in somatic cells but, in XX as well as XXY fetuses, both parental alleles were expressed in germ cell-enriched cell populations. Because testis differentiation is temporally and morphologically normal in the XXY testis and because all germ cells embark upon a male pathway of development, these results provide compelling evidence that X chromosome reactivation in fetal germ cells is independent of the somatic events of sexual differentiation. Proper X chromosome dosage is essential for the normal fertility of male mammals, and abnormalities in germ cell development are apparent in the XXY testis within several days of X reactivation. Studies of exceptional germ cells that survive in the postnatal XXY testis demonstrated that surviving germ cells are exclusively XY and result from rare nondisjunctional events that give rise to clones of XY cells.