Hox gene expression in limbs: colinearity by opposite regulatory controls

Genes of the HoxD complex have a crucial role in the morphogenesis of vertebrate limbs. During development, their functional domains are colinear with their genomic positions within the HoxD cluster such that Hoxd13 and Hoxd12 are necessary for digit development, whereas Hoxd11 and Hoxd10 are involved in making forearms. Mutational analyses of these genes have demonstrated their importance and illustrated the requirement for a precise control of their expression during early limb morphogenesis. To study the nature of this control, we have scanned the posterior part of the HoxD complex with a targeted reporter transgene and analyzed the response of this foreign promoter to limb regulatory influences. The results suggest that this regulation is achieved through the opposite effects of two enhancer elements which would compete with each other for interacting with nearby-located promoters. The physical position of a given gene within this genomic interval of opposite regulations might thus determine its final expression pattern. This model provides a conceptual link between the morphology of the future limb and the genetic organization of the Hox gene cluster, a translation of a genomic context into a morphogenetic topology.     

Conserved expression domains for genes upstream and within the HoxA and HoxD clusters suggests a long-range enhancer existed before cluster duplication

The posterior HoxA and HoxD genes are essential in appendicular development. Studies have demonstrated that a "distal limb enhancer," remotely located upstream of the HoxD complex, is required to drive embryonic autopod expression of the posterior Hox genes as well as the two additional non-Hox genes in the region: Evx2 and Lnp. Our work demonstrates a similar mode of regulation for Hoxa13 and four upstream genes: Evx1, Hibadh, Tax1bp, and Jaz1. These genes all show embryonic (E11.5-E13.5) distal limb and genital bud expression, suggesting the existence of a nearby enhancer influencing the expression of a domain of genes. Comparative sequence analysis between homologous human and mouse genomic sequence upstream of Hoxa13 revealed a remote 2.25-kb conserved noncoding sequence (mmA13CNS) within the fourth intron of the Hibadh gene. mmA13CNS shares a common 131-bp core identity within a conserved noncoding sequence upstream of Hoxd13, which is located within the previously identified distal limb enhancer critical region. To test the function of this conserved sequence, we created mmA13CNS-Hsp86-lacZ transgenic mice. mmA13CNS directed a wide range of tissue expression, including the central nervous system, developing olfactory tissue, limb, and genital bud. Limb and genital bud expression directed by mmA13CNS is not identical to the patterns exhibited by Hoxa13/Evx1/Hibadh/Tax1bp1/Jaz1, suggesting that mmA13CNS is not sufficient to fully recapitulate their expression in those tissues. The Evx1- and Evx2-like central nervous system expression observed in these mice suggests that the long-range regulatory element(s) for the Hox cluster existed before the cluster duplication.     

The chick oligozeugodactyly (ozd) mutant lacks sonic hedgehog function in the limb

We have analyzed a new limb mutant in the chicken that we name oligozeugodactyly (ozd). The limbs of this mutant have a longitudinal postaxial defect, lacking the posterior element in the zeugopod (ulna/fibula) and all digits except digit 1 in the leg. Classical recombination experiments show that the limb mesoderm is the defective tissue layer in ozd limb buds. Molecular analysis revealed that the ozd limbs develop in the absence of Shh expression, while all other organs express Shh and develop normally. Neither Ptc1 nor Gli1 are detectable in mutant limb buds. However, Bmp2 and dHAND are expressed in the posterior wing and leg bud mesoderm, although at lower levels than in normal embryos. Activation of Hoxd11-13 occurs normally in ozd limbs but progressively declines with time. Phase III of expression is more affected than phase II, and expression is more severely affected in the more 5' genes. Interestingly, re-expression of Hoxd13 occurs at late stages in the distal mesoderm of ozd leg buds, correlating with formation of digit 1. Fgf8 and Fgf4 expression are initiated normally in the mutant AER but their expression is progressively downregulated in the anterior AER. Recombinant Shh protein or ZPA grafts restore normal pattern to ozd limbs; however, retinoic acid fails to induce Shh in ozd limb mesoderm. We conclude that Shh function is required for limb development distal to the elbow/knee joints, similar to the Shh(-/-) mouse. Accordingly we classify the limb skeletal elements as Shh dependent or independent, with the ulna/fibula and digits other than digit 1 in the leg being Shh dependent. Finally we propose that the ozd mutation is most likely a defect in a regulatory element that controls limb-specific expression of Shh.     

An examination of the Chiropteran HoxD locus from an evolutionary perspective

SUMMARY Duplications of Hox gene clusters have been suggested as a mechanism whereby new Hox functions can be developed while preserving critical ancestral roles. However, in tetrapods, particularly in mammals, there is great variability in limb structure morphologies that are known to be affected by Hox genes without further Hox cluster duplications. The lack of further duplications suggests that if Hox genes have played a direct role in the morphological elaboration of tetrapod limbs, the changes must have come about from Hox protein sequence changes or from changes regarding the amount, time, and place of Hox gene expression. To investigate whether such changes to Hox genes could play a role in limb elaboration, we examined the HoxD locus in bats, which have both highly elaborated fore‐ and hindlimbs. We found that while the Chiropteran HoxD13 protein was highly conserved, there was an expansion of HoxD13 expression in the posterior portion of the Chiropteran forelimb and into the leading edge of the wing membrane. We were also able to uncover a number of unique lineage‐specific sequence changes to a known HoxD limb enhancer, the Global Control Region (GCR). Further, mouse transgenic assays showed that the Chiropteran GCR has new limb enhancer activity domains beyond that reported for the Human GCR. These results suggest that modulation of Hox gene expression may be a mechanism for effecting morphological change in lineage‐specific manner while maintaining ancestral constraints and cluster integrity.     

The expression pattern of the chicken homeobox-containing gene GHox-7 in developing polydactylous limb buds suggests its involvement in apical ectodermal ridge-directed outgrowth of limb mesoderm and in programmed cell death

Abstract. The limb buds of the polydactylous mutant embryos, talpid ² and diplopodia -5, possess expanded distal apexes surmounted by prolongated thickened apical ectodermal ridges that promote the outgrowth and formation of digits from both the anterior and posterior mesoderm of the mutant limb buds. The chicken homeobox-containing gene GHox-7 exhibits an expanded domain of expression throughout the expanded subridge mesoderm of the mutant limb buds, providing support for the hypothesis that GHox-7 expression by subridge mesenchymal cells is involved in the outgrowth-promoting effect of the apical ectodermal ridge. During normal limb development GHox-7 is also expressed by the mesoderm in the proximal anterior nonchondrogenic periphery of the limb bud, which includes, but is not limited to the anterior necrotic zone. GHox-7 is also expressed in the posterior necrotic zone at the mid-proximal posterior edge of the limb bud. In contrast, GHox-7 is not expressed in either the proximal anterior or posterior peripheral mesoderm of talpid ² and diplopodia -5 limb buds which lack proximal anterior and posterior necrotic zones. Furthermore, retinoic acid-coated bead implants, which diminish cell death in the anterior necrotic zone, elicit a local inhibition of GHox-7 expression in the proximal anterior peripheral mesoderm. These results support the suggestion that GHox-7 may be involved in defining regions of programmed cell death during limb development. Furthermore, these studies indicate that the distal subridge and proximal anterior nonchondrogenic mesodermal domains of GHox-7 expression are independently regulated.     

qPCR array检测分析 C57BL/6小鼠胚胎后肢发育基因表达谱

目的:胚胎生育过程中因肢体发育异常造成的出生缺陷比率不低,其相关基因表达模式尚不明确。本实验通过建立实时定量PCR芯片(Real-time quantitative polymerasechain reaction array,qPCR array)检测方案,研究C57BL/6品系小鼠后肢发育相关基因的表达谱。方法:以同源异形盒基因家族(Hox)、Wnt5a、配对同源结构域基因(Pitx1)、成纤维生长因子(Fgf8)、音猬因子(Shh)等小鼠肢体发育相关的重要基因制作基因检测表达谱,以C57BL/6品系怀孕雌鼠为材料,取胚胎肢芽发育的四个关键时期(E10.5,E11.5,E12.5,E13.5)的胎鼠后肢,利用qPCR array方案检测表达谱中基因的相对表达水平差异。结果:通过已建立的qPCR array检测了C57BL/6品系小鼠胚胎后肢发育时期Hox家族、Wnt5a、Pitx1、Fgf8、Shh等基因的表达差异。以E10.5为对照,检测出在后肢发育时期基因呈三种表达模式,即Hoxb6、Hoxb8、Hoxc8、Hoxc9、Hoxc10、Hoxd9和Shh基因的表达水平呈上调;Hoxa11、Hoxa13、Hoxc12、Hoxc13、Hoxd13等基因表达出现下调;Hoxc9、Hoxc10、Hoxc11、Hoxd9、Hoxd12、Fgf8和Pitx1等基因的相对表达量呈先上调后下调的曲线表达模式,且有少部分基因在小鼠后肢发育时期表达水平无明显变化。结论:Hox家族、Wnt5a、Pitx1、Fgf8、Shh等基因在小鼠后肢发育时期表达,并且表达模式存在明显差异。     

A gradient of gap junctional communication along the anterior-posterior axis of the developing chick limb bud.

A modification of the scrape-loading/dye transfer technique was used to study gap junctional communication along the anterior-posterior (A-P) axis of embryonic chick wing buds at an early stage of development (stage 20/21) when positional values along the A-P axis are being specified. Extensive intercellular transfer of the gap junction-permeable dye, lucifer yellow, from scrape-loaded mesenchymal cells to contiguous cells occurs in the posterior mesenchymal tissue of the wing bud adjacent to the zone of polarizing activity, which is thought to be the source of a diffusible morphogen that specifies A-P positional identity according to its local concentration. Considerably less transfer of lucifer yellow dye occurs in scrape-loaded mesenchymal tissue in the middle of the limb bud compared to posterior mesenchymal tissue, and little or no transfer of lucifer yellow is observed in the mesenchymal tissue in the anterior portion of the limb bud. No intercellular transfer of the gap junction-impermeable dye, rhodamine dextran, occurs in any region of the limb bud. These results indicate that there is a gradient of gap junctional communication along the A-P axis of the developing chick wing bud. This gradient of gap junctional communication along the A-P axis might generate a graded distribution of a relatively low molecular weight intracellular regulatory molecule involved in specifying A-P positional identities.     

Role of the chicken homeobox-containing genes GHox-4.6 and GHox-8 in the specification of positional identities during the development of normal and polydactylous chick limb buds.

During early stages of normal chick limb development, the homeobox-containing (HOX) gene GHox-4.6 is expressed throughout the posterior mesoderm of the wing bud from which most of the skeletal elements including the digits will develop, whereas GHox-8 is expressed in the anterior limb bud mesoderm which will not give rise to skeletal elements. In the present study, we have examined the expression of GHox-4.6 and GHox-8 in the wing buds of two polydactylous mutant chick embryos, diplopodia-5 and talpid2, from which supernumerary digits develop from anterior limb mesoderm, and have also examined the expression of these genes in response to polarizing zone grafts and retinoic acid-coated bead implants which induce the formation of supernumerary digits from anterior limb mesoderm. We have found that the formation of supernumerary digits from the anterior mesoderm in mutant and experimentally induced polydactylous limb buds is preceded by the ectopic expression of GHox-4.6 in the anterior mesoderm and the coincident suppression of GHox-8 expression in the anterior mesoderm. These observations suggest that the anterior mesoderm of the polydactylous limb buds is "posteriorized" and support the suggestion that GHox-8 and GHox-4.6, respectively, are involved in specifying the anterior non-skeletal and posterior digit-forming regions of the limb bud. Although the anterior mesodermal domain of GHox-8 expression is severely impaired in the mutant and experimentally induced polydactylous limb buds, this gene is expressed by the prolonged, thickened apical ectodermal ridges of the polydactylous limb buds that extend along the distal anterior as well as the distal posterior mesoderm.(ABSTRACT TRUNCATED AT 250 WORDS)     

Targeted disruption of Hoxd9 and Hoxd10 alters locomotor behavior, vertebral identity, and peripheral nervous system development

The five most 5' HoxD genes, which are related to the Drosophila Abd-B gene, play an important role in patterning axial and appendicular skeletal elements and the nervous system of developing vertebrate embryos. Three of these genes, Hoxd11, Hoxd12, and Hoxd13, act synergistically to pattern the hindlimb autopod. In this study, we examine the combined effects of two additional 5' HoxD genes, Hoxd9 and Hoxd10. Both of these genes are expressed posteriorly in overlapping domains in the developing neural tube and axial mesoderm as well as in developing limbs. Locomotor behavior in animals carrying a double mutation in these two genes was altered; these alterations included changes in gait, mobility, and adduction. Morphological analysis showed alterations in axial and appendicular skeletal structure, hindlimb peripheral nerve organization and projection, and distal hindlimb musculature. These morphological alterations are likely to provide the substrate for the observed alterations in locomotor behavior. The alterations observed in double-mutant mice are distinct from the phenotypes observed in mice carrying single mutations in either gene, but exhibit most of the features of both individual phenotypes. This suggests that the combined activity of two adjacent Hox genes provides more patterning information than activity of each gene alone. These observations support the idea that adjacent Hox genes with overlapping expression patterns may interact functionally to provide patterning information to the same regions of developing mouse embryos.     

Wnt-7a in feather morphogenesis: involvement of anterior-posterior asymmetry and proximal-distal elongation demonstrated with an in vitro reconstitution model.

How do vertebrate epithelial appendages form from the flat epithelia? Following the formation of feather placodes, the previously radially symmetrical primordia become anterior-posterior (A-P) asymmetrical and develop a proximo-distal (P-D) axis. Analysis of the molecular heterogeneity revealed a surprising parallel of molecular profiles in the A-P feather buds and the ventral-dorsal (V-D) Drosophila appendage imaginal discs. The functional significance was tested with an in vitro feather reconstitution model. Wnt-7a expression initiated all over the feather tract epithelium, intensifying as it became restricted first to the primordia domain, then to an accentuated ring pattern within the primordia border, and finally to the posterior bud. In contrast, sonic hedgehog expression was induced later as a dot within the primordia. RCAS was used to overexpress Wnt-7a in reconstituted feather explants derived from stage 29 dorsal skin to further test its function in feather formation. Control skin formed normal elongated, slender buds with A-P orientation, but Wnt-7a overexpression led to plateau-like skin appendages lacking an A-P axis. Feathers in the Wnt-7a overexpressing skin also had inhibited elongation of the P-D axes. This was not due to a lack of cell proliferation, which actually was increased although randomly distributed. While morphogenesis was perturbed, differentiation proceeded as indicated by the formation of barb ridges. Wnt-7a buds have reduced expression of anterior (Tenascin) bud markers. Middle (Notch-1) and posterior bud markers including Delta-1 and Serrate-1 were diffusely expressed. The results showed that ectopic Wnt-7a expression enhanced properties characteristic of the middle and posterior feather buds and suggest that P-D elongation of vertebrate skin appendages requires balanced interactions between the anterior and posterior buds.