Permissive and instructive Hox codes govern limb positioning

Yajun Wang; Maik Hintze; Jinbao Wang; Patrick Petzsch; Karl Köhrer; Hengxun Tao; Longfei Cheng; Peng Zhou; Jianlin Wang; Zhaofu Liao; Xufeng Qi; Dongqing Cai; Thomas Bartolomaeus; Karl Schilling; Joerg Wilting; Stefanie Kuerten; Georgy Koentges; Ketan Patel; Qin Pu; Ruijin Huang

doi:10.7554/eLife.100592.1

eLife Assessment

This study investigates the role of Hox genes in determining the position of the forelimb bud using experimental loss- and gain-of-function approaches in chicken embryos, concluding that Hox4 and Hox5 provide permissive signals for forelimb formation throughout the neck region, while the final forelimb position is determined by the instructive signals of Hox6/7 in the lateral plate mesoderm. These results could potentially be fundamental to our understanding of Hox patterning. However, the evidence supporting these conclusions is incomplete; while the gain-of-function experiments are well supported, the loss-of-function experiments using dominant-negative constructs lack sufficient controls, and could be the result of an experimental artifact.

https://doi.org/10.7554/eLife.100592.1.sa3

Significance of findings

fundamental: Findings that substantially advance our understanding of major research questions

landmark
fundamental
important
valuable
useful

Strength of evidence

incomplete: Main claims are only partially supported

exceptional
compelling
convincing
solid
incomplete
inadequate

During the peer-review process the editor and reviewers write an eLife assessment that summarises the significance of the findings reported in the article (on a scale ranging from landmark to useful) and the strength of the evidence (on a scale ranging from exceptional to inadequate). Learn more about eLife assessments

Abstract

The positioning of limbs along the anterior-posterior axis varies widely across vertebrates. The mechanisms controlling this feature remain to be fully understood. For over 30 years, it has been speculated that Hox genes play a key role in this process but evidence supporting this hypothesis has been largely indirect. In this study, we employed loss- and gain-of-function Hox gene variants in chick embryos to address this issue. Using this approach, we found that Hox4/5 genes are necessary but insufficient for forelimb formation. Within the Hox4/5 expression domain, Hox6/7 genes are sufficient for reprogramming of neck lateral plate mesoderm to form an ectopic limb bud, thereby inducing forelimb formation anterior to the normal limb field. Our findings demonstrate that the forelimb program depends on the combinatorial actions of these Hox genes. We propose that during the evolutionary emergence of the neck, Hox4/5 provide permissive cues for forelimb formation throughout the neck region, while the final position of the forelimb is determined by the instructive cues of Hox6/7 in the lateral plate mesoderm.

Impact statement

Elucidation of the Hox code defining forelimb positioning provides novel insights in lateral plate mesoderm patterning and the integration of vertebrate column structure and limb positioning.

Classification

Development --- developmental biology

Introduction

The spatial development of vertebrate tissues is regulated by Homeobox (Hox) genes (Duboule, 2022; Iimura & Pourquie, 2006; Zakany & Duboule, 2007). A huge literature evidences that Hox genes determine the development and patterning of the vertebrate axial skeleton (reviewed in Burke, 2000). Mutations in Hox genes can lead to homeotic transformations, where one type of vertebra is transformed into another (Böhmer, 2017). Vertebrate limbs emerge at specific axial levels along the anterior-posterior (AP) axis, with precise positioning varying significantly across species (Burke et al., 1995). These characteristics make limb positioning a valuable experimental model for studying the mechanisms regulating positional information (Zakany & Duboule, 2007). Despite variable numbers of cervical vertebrae between species, the pectoral fin or forelimb is always located at the cervical-thoracic boundary. The mechanisms underpinning the positioning of vertebrate forelimbs remain to be fully elucidated.

While Hox gene misexpression causes substantial alterations in vertebrae identity (Garcia-Gasca & Spyropoulos, 2000; Horan et al., 1995; Jeannotte et al., 1993; Ramfrez-Solisn et al., 1993), only minor changes in limb development have been observed in Hox gene mutants (Rancourt et al., 1995). It is therefore unclear whether, for example, the abnormal limb that develops in Hoxb5 mutants represents a true shift in the limb field or rather a shoulder girdle defect causing the forelimb to appear “shrugged” anteriorly. In fact, whereas knockdown of the complete paralogous group Hox5 genes results in changes in limb patterning, it does not result in a positional shift of the forelimb (Xu et al., 2013).

Moreover, interpretation of the effects of Hox genes on limb positioning in global knockouts is fraught by the fact that this not only affects lateral plate mesoderm patterning, but invariably also vertebrae-forming mesoderm and vertebrate identity. Yet normal vertebrate identity is required as a reference for defining limb positions. Ideally, limb positioning should be investigated by limiting the manipulation of Hox expression to the limb-forming mesoderm, without altering vertebral positional identity.

The initiation of the forelimb program is marked by Tbx5 expression in the LPM, which is functionally required for pectoral fin formation in zebrafish and forelimb formation in chicken and mice (Hasson, Del Buono, & Logan, 2007; Rallis et al., 2003; Takeuchi et al., 2003). However, the forelimb-forming potential is present in mesodermal cells at the cervico-thoracic transitional zone long before the activation of Tbx5 expression (Chaube, 1959; Moreau et al., 2019). This has led to the notion that cells first acquire positional identity through the expression of Hox genes, followed by a developmental program guided by their positional history (Duboule, 2022; Iimura, 2006; Zakany and Duboule, 2007).

The positional identity of future limb forming cells of the LPM is coded by the nested and combinatorial expression of Hox genes (Duboule & Dollé, 1989; Kessel & Gruss, 1991). Only a few studies have investigated how this Hox code translates to Tbx5 expression in the prospective forelimb region and thus regulates forelimb positioning (Moreau et al., 2019). During gastrulation, the collinear activation of Hox genes begins in the epiblast, conferring anterior-posterior identity to the paraxial mesoderm (Duboule, 2022; Iimura & Pourquie, 2006). A similar mechanism regulates the anteroposterior patterning of the LPM, which gives rise to limbs. For instance, Hoxb4-expressing cells emigrating from the posterior part of the primitive streak form the LPM in the neck. Subsequently, Hoxb4 activates Tbx5 expression within this LPM domain. The limb positioning is thus regulated by Hox genes in two phases (Minguillon et al., 2012; Moreau et al., 2019; Nishimoto et al., 2014). During the first phase, Hox-regulated gastrulation movements establish the forelimb, interlimb and hindlimb domains in the LPM. In the second phase, a Hox code regulates Tbx5 activation in the forelimb-forming LPM (Minguillon et al., 2012; Moreau et al., 2019; Nishimoto et al., 2014). The forelimb-forming Hox code is considered to be constituted by both repressing and enhancing Hox genes: Caudal Hox genes, including Hox9, suppress and thus limit Tbx5 expression, whereas rostrally expressed Hox genes activate Tbx5 expression (Minguillon et al., 2012; Nishimoto et al., 2014). To date, HoxPG4 and PG5 genes are considered as activators of Tbx5 (Minguillon et al., 2012; Nishimoto et al., 2014). The function of PG6 and PG7 genes (Becker et al., 1996; Becker, Jiang, et al., 1996), which are also prominently expressed in the forelimb region, has so far not been analysed.

Here, we aimed to investigate which Hox genes act to position the anterior limb in chicks. We present evidence that wing position is controlled by a permissive signal governed by HoxPG4/5 which demarcates a territory where it can form. However, an addition instructive cue mediated by HoxPG6/7 genes within the permissive region is required for forelimb formation. Our study is the first to show that neck LPM can be re-specified to form limb.

Results

HoxPG4–7 are required for the forelimb formation

The expression domain of HoxPG6/7, like that of HoxPG4/5, overlaps with the forelimb field, suggesting they might activate Tbx5 expression. To untangle the roles of individual members of the HoxPG4/5/6/7, we performed loss-of-function experiments in chick embryos. We focused on the A-cluster of HoxPG4/5/6/7, using specifically generated dominant-negative (DN) forms to suppress the signalling function of each target Hox gene. The DN variants lack the C-terminal portion of the homeodomain, rendering them incapable of binding to the target DNA while preserving their function of binding transcriptional specific co-factors (Denans et al., 2015; Gehring et al., 1990). Plasmids expressing dominant-negative Hoxa4, a5, a6 or a7 were electroporated into the dorsal layer of LPM in the prospective wing field, from which the wing mesoderm originates in Hamburger-Hamilton stage (HH) 12 chick embryos (Hamburger & Hamilton, 1951) (Fig. 1a, b). After 8 – 10 h, embryos reached HH14 when expression from the transfected DN-constructs was detectable in the wing field of the transfected (right) side signified by Enhanced Green Fluorescent Protein (EGFP) expression also encoded by these plasmids (Fig. 1c).

Hoxa4/a5/a6/a7 genes are necessary for wing bud formation.
Schemes showing the electroporation in transverse section (a) and in the dorsal view (b). The somite 16 is marked (b). Successful transfection of plasmids as verified by EGFP expression(c). The *dn Hox* genes downregulated the expression of Tbx5 (B-E), Fgf10 (G-J), and Fgf8 (L-O) and inhibited wing bud formation at the ipsilateral (right) side (Q-T). A-E: HH14; F-O: HH18-19; P-T: HH22; scale bars in c (for c, A-O) and in P (for P-T): 500μm. The proximodistal (P-D) distance (left in U) of wing buds is significantly reduced in *Hox dn*-expressing wing buds compared to EGFP electroporated wing buds (right in U). The scheme on the left-hand side shows how measurements were made. Red dotted line: baseline of the wing bud; CTRL: normal control wing buds without any operation; Elect.: wing buds after electroporation without constructs; GFP: wing buds after electroporation with EGFP-expressing constructs; A4dn, A5dn, A6dn, A7dn: wing buds after electroporation with dn Hoxa4/5/6/7 expressing constructs, respectively. Each dot represents one embryo; error bars represent mean ±SEM. **p < 0.01.

Tbx5 as the first gene indicating activation of the forelimb-forming program starts to be expressed in the forelimb field of normal chick embryos at HH13 (http://geisha.arizona.edu). Therefore, we analysed Tbx5 expression following inhibition of Hoxa4/5/6/7 at HH14. Expression of Tbx5 in the wing field transfected with DN plasmids for any of these genes was consistently lower than in the contralateral (control) side (Fig. 1B-E, Table 1). The down-regulation of Tbx5 expression by all four dominant-negative forms of Hoxa4/5/6/7 shows a previously unknown requirement of PG6 and PG7 Hox genes for the activation of Tbx5 during forelimb induction, and confirms the previously reported Tbx5 activating effects of PG4 and PG5 Hox genes (Nishimoto et al., 2014)

Dominant negative expression of Hoxa4/a5/a6/a7 down-regulated gene expression.
The numbers of embryos with an unambiguous effect and the total number of embryos analysed are given (effect/total number analysed).

Tbx5 is required for the activation of Fgf10 in the mesoderm (Cohn et al., 1995; Min et al., 1998; Sekine et al., 1999; Young et al., 2019). Fgf10 subsequently induces Fgf8 expression in the overlying ectoderm to initiate forelimb outgrowth (Barrow et al., 2003). The two genes form a positive feedback loop to ensure formation of the apical ectodermal ridge (AER), which ultimately regulates sustainable outgrowth and patterning (Crossley et al., 1996; Min et al., 1998). We analysed their expression at HH18-19. Dominant-negative inhibition of any of the Hoxa4/5/6/7 genes reduced the expression levels and domains of Fgf10 (Fig. 1G-J; Table 1) and Fgf8 (Fig. 1L-O; Table 1). The consequence of these manipulations on the outgrowth of the wing bud was analysed at HH22, when the wing bud develops a nearly square shape. After inhibition of HOX proteins, the form of the target wing buds was altered and their size was decreased. In some cases, the anteroposterior extent of the wing bud was also remarkably reduced (Fig. 1Q-T). To quantify the effect of Hox inhibition on wing bud development, we measured the proximal-distal (P-D) elevation of the electroporated wing bud above the trunk lateral surface, compared to the contralateral non-electroporated control wing bud (Fig. 1U).

Electroporation of plasmid-free solution and an EGFP-encoding plasmid caused only minimal reduction compared to their contralateral wing bud, indicating low developmental toxicity of the procedure of electroporation itself (Fig. 1U).

Interference with the action of the representative A-cluster Hox genes indicate that Hox genes from all four paralogous groups (PG4, PG5, PG6 and PG7) impinge on the forelimb program and should be considered part of the activating Hox code for forelimb development. Overall, the effect of each Hox gene is limited, suggesting they act in a combinatorial, and possibly redundant fashion.

Hox6/7 but not Hox4/5 are sufficient to reprogram neck to wing mesoderm

We next investigated the role of HoxPG6/7 during forelimb fate determination. We hypothesized that if HoxPG6/7 are (an) integral and necessary part(s) of the forelimb Hox code, their ectopic expression in a non-limb region, similar to the limb-inducing activity of FGFs (Cohn et al., 1995), should induce forelimb formation. In the present study, the neck was chosen as the non-limb region.

When A-cluster genes were electroporated at HH11–12 into the dorsal LPM at the level of somites 10–14 (anterior to the wing field) (Fig. 2a), strong expression could be verified anterior to the cognate wing field by in situ hybridization (ISH) 12h after electroporation (Fig. 2b-e), indicating successful expression of Hox gene constructs.

Hoxa6/a7 but not *Hoxa4/a5* are sufficient to induce a neck wing bud.
Scheme showing electroporation of the neck region in the dorsal view (a). The somite 16 is marked. The expression domain of electroporated constructs is marked by a green bar. Expression of *Hoxa4*(b), *Hoxa5*(c), *Hoxa6*(d), *Hoxa7*(e) in the LPM anterior to the wing field after electroporation with the respective plasmids as documented by in situ hybridization. Whereas ectopic cervical expression of *Hoxa6/a7* induced the anterior expression (indicated by arrows) of *Tbx5* (**D, E, I, J**), overexpression of *Hoxa4/a5* did not induce anterior expression of it (**B, C, G, H**). Also, only Hoxa6 and Hoxa7, but not a4 or a5 resulted in the anterior extension of the wing bud (arrows in I-J). The ectopic wing buds (fused with or separated from the endogenous one) induced by *HoxPG6-7* are indicated by GFP fluorescence (K-O) and in situ hybridization for *Tbx5* (arrows in P-T). b-e and **A-E**: HH14; **F-T**: HH22; scale bars in b (for **b-e** and A-E), in F (for F-J) and in K (for K-T): 500μm. Arrows indicate induced wing buds (**P-T**).

The anterior expression domain of HoxPG6/7 overlaps with the forelimb field but does not extend into the neck region. Electroporation of constructs expressing Hoxa6/7 into the neck mesoderm caused their ectopic expression anterior to the forelimb field (Fig. 2d, e). This induced ectopic expression of Tbx5 in this region anterior to the cognate wing field (Fig. 2D, E). By 48h re-incubation, a bulge appeared in the neck region transfected with Hoxa6/7. This bulge expressed the forelimb master gene Tbx5, and expression strength was similar to that of the natural wing bud (Fig. 2I, J). Hence, it can be considered as an ectopic wing bud in the neck.

In contrast to ectopic expression of Hoxa6/7 in the neck region, overexpression of Hoxa4/5 (Fig. 2b, c) by electroporating this region with Hoxa4/5 coding plasmids did not extend Tbx5 expression anteriorly (Fig. 2B, C), indicating that no wing-forming mesoderm was ectopically induced in the neck by Hoxa4/5 overexpression. Consequently, no structure emerged from the neck anterior to the endogenous wing bud after 48 h of re-incubation (Fig. 2G, H). These results demonstrate that Hoxa4 and Hoxa5 are insufficient, whereas Hoxa6 and Hoxa7 are sufficient to specify wing mesoderm in the neck region.

To ascertain whether other members of HoxPG6/7 share the forelimb-inducing activity of the A-cluster genes, plasmids encoding full-length Hoxb6 and Hoxc6, as well as Hoxa7 and Hoxb7, were ectopically expressed in the region anterior to the wing field. After 48 h, we observed either an anteriorly extended wing bud or a separated bud in the neck anterior to the endogenous wing bud (n = 226/440, Table 2). The efficiency of transfection and transcription was monitored by assessing EGFP expression from the plasmids used (Fig. 2K-O), and their wing-inducing effect by screening induced Tbx5 expression (Fig. 2P-T). In more than half of the embryos, a separate wing bud, indicated by Tbx5 expression, formed anteriorly to the endogenous wing bud (n = 128/226, Table 2). In the remaining embryos, the endogenous wing bud appeared extended anteriorly (n = 98/226, Table 2). These findings demonstrate that the ectopic formation of a wing bud in the neck is a consequence of the expression of all members of the HoxPG6/7 gene family.

HoxPG6/7 upregulated wing bud formation in the neck region.
Number indicate the numbers of embryos in which a cervical extension of the wing bud, or a cervical wing bud separated from the normal wing bud could be observed.

Curiously, the induced wing buds did not grow distally to any great degree and remained small after 48h of re-incubation. To elucidate this phenomenon, RNA sequencing was used to compare gene expression in the induced wing buds with that of normal wing buds. Each group (Fig. 3A) was comprised of four replicates. Functional categorization revealed that genes classified by gene ontology (GO) biological process terms “anterior/posterior pattern specification” (p_genuine = 3.2^-10; p_induced = 2.5^-10), proximal/distal pattern formation” (p_genuine = 3.7^-9; p_induced = 8.7^-9), “regulation of transcription from RNA polymerase II promoter” (p_genuine = 8.4^-11; p_induced = 3.2^-8), “embryonic skeletal system morphogenesis” (p_genuine = 2.0^-9; p_induced = 1.3^-5), and “embryonic limb morphogenesis” (p_genuine = 8.1^-9; p_induced = 1.4^-4) were enriched in tissue of the genuine limb bud and in limb buds induced by Hoxa6 overexpression (Table 3). In contrast, genes associated with the biological process terms “cell adhesion” (p = 4.3^-19), “extracellular matrix organization” (p = 4.2^-15), “transmembrane receptor protein tyrosine kinase signaling pathway” (p = 4.8^-13), “positive regulation of kinase activity” (p = 1.6^-10) and “multicellular organism development” (p = 3.1^-9) were overrepresented among the genes enriched in neck tissue (Table 3). Ectopic expression of Hoxa6 resulted in the up-regulation of multiple genes shared with normal wing buds, and the gene expression pattern in A6-induced wing buds was more similar to that of cognate wing buds than to that of native neck tissue (Fig. 3B, B’). Gene ontology biological process terms for 221 genes showed that the A6-induced bud closely resembles a normal wing bud (Fig. 3C). These findings demonstrate that Hoxa6 is sufficient for wing bud induction.

The neck wing bud is smaller than the natural wing bud.
The scheme (A) indicates how tissue samples were collected for RNA sequencing. Venn diagram (B) showing the overlap between up-regulated genes expressed in normal wing bud (Wing 948), HoxA6-induced wing bud (A6-Bud 347) and neck tissue (Neck 2202) in the cervical LPM; the heatmap (B’) showing the expression profiles of genes in neck tissue, normal wing bud and HoxA6-induced wing bud. FC: fold change. Gene Ontology (C) analyses showing top 15 terms in biological process for 221 genes of A6-Bud. The heatmap (D) shown the expression levels of genes related to outgrowth, patterning. The expression of *Fgf10* (E, F), *Fgf8* (G, H), *Shh* (I) and *Lmx1* (J) in transfected embryos is rechecked by ISH. E and G: HH18-19; F, H, I and J: HH22; scale bars in E (for E, G) and in F (for F, H-J): 500μm. Arrows indicate induced wing buds.

Gene Ontology analyses showing top ten terms in Biological Process.

Although the wing program in A6-bud revealed by Tbx5 was initiated, the AER was not established. Expression of Fgf10 was activated in the neck, resulting in the initiation of mesodermal outgrowth. However, its expression level was lower than that of the physiological wing-forming mesoderm (Fig. 3D-F). In contrast, Fgf8 was not induced in the ectoderm (Fig. 3D, G, H). Thus, the feedback loop between Fgf10 and Fgf8 was missing in the induced wing bud, and it failed to form an AER. Failure of the formation of functional AER is also indicated by the low levels of Shh expression in the induced wing bud as compared to the physiological wing anlage (Fernandez-Guerrero et al., 2022; Lin & Zhang, 2020). Without AER, the induced wing bud did not grow further. Further, the Zone of Polarizing Activity (ZPA) identified by the expression of Shh was not established (Fig. 3D, I). Finally, we noted that the induced wing bud was dorsalized, as indicated by the strongly upregulated expression of Lmx1 (Fig. 3D, J).

Taken together, we conclude that HoxPG6/7 genes are sufficient for forelimb specification in the neck region. However, the induced wing bud is incapable of establishing the positive feedback loop between Fgf8 and Fgf10 due to the inability of Fgf signal transduction in the neck ectoderm (Lours & Dietrich, 2005).

Discussion

In this study, we investigated how Hox genes determinate the forelimb cell fate of the LPM, thus the positioning of the forelimb. We found that functional inhibition of the A-cluster Hox4/5/6/7 genes, on the protein level, using dominant-negative forms, resulted in reduction of Tbx5 expression and subsequently of forelimb formation. Expression of PG6/7 but not of PG4/5 Hox genes could reprogram neck mesoderm to limb-forming mesoderm. These findings indicate different roles of PG6/7 and PG4/5 Hox genes during forelimb formation.

PG4/5/6/7 genes constitute the Hox code activating forelimb formation

In previous genetic studies, it has been shown that, in cooperation with Wnt and retinoic acid (RA) signalling (Nishimoto, Wilde, Wood, & Logan, 2015), HoxPG4/5 genes activate Tbx5 expression (Minguillon et al., 2012; Nishimoto et al., 2014; Moreau et al., 2019). Tbx5 then activates Fgf10 expression, which leads to the thickening and epithelio-mesenchymal transition of the LPM, initiating the formation of the primary forelimb bud (Delgado et al., 2021; Gros & Tabin, 2014). Subsequently, mesodermal Fgf10 induces ectodermal Fgf8 expression, creating a positive feedback loop that sustains the outgrowth of the limb bud. Experiments with dominant-negative forms suggest that not only HoxPG4/5 but also HoxPG6/7 are required for the Tbx5 expression in the LPM and thus for forelimb formation. Functional inhibition of any of the A-cluster of PG4/5/6/7 Hox genes down-regulated Tbx5, as well as subsequent Fgf10 and Fgf8 expression. The resultant lower activity of the Fgf10-Fgf8 feedback loop ultimately limited the further development of the wing buds.

In summary, our loss-of-function experiments provide direct evidences for the requirement of PG4/5/6/7 Hox genes for forelimb formation. Consequently, in addition to PG4/5, PG6/7 genes also constitute the Hox code that activates the forelimb-forming program.

PG6/7 genes are sufficient for forelimb formation

Ectopic expression of HoxPG6/7 genes activated Tbx5 expression and initiated the wing-forming program in the neck LPM. Importantly, the induced wing bud in the neck did not grow sustainably. This may be linked to the reduced, or rather absent function of the FGF10-FGF8 feedback loop in the induced wing bud (Cohn & Tickle, 1999; Yin et al., 2016). The neck has previously been classified as a “limb-incompetent” region, where the limb formation can only occur when both limb mesoderm and limb ectoderm are simultaneously transplanted to the neck. Transplantation of limb mesoderm alone under neck ectoderm does not support limb formation (Lours & Dietrich, 2005). The re-specified wing mesoderm by HoxPG6/7 in the neck is still covered by neck ectoderm. This condition is similar to the transplantation of the prospective limb mesoderm to the neck without limb ectoderm (Lours & Dietrich, 2005). Since the neck ectoderm is incapable of Fgf signal transduction, lacking Fgf8-Fgf10 feedback loop and AER, the development of the induced wing bud stalled in the pre-AER phase.

The wing buds seen following PG6/7 expression in the neck resemble the wing anlagen in the chicken limbless mutant, in which Fgf8 expression is mutated, and that lacks the AER and, like the induced limb buds here, the zone of polarizing activity (Grieshammer et al., 1996; Ros et al., 1996; Vogel et al., 1996). Moreover, both the induced neck wing-buds observed here and the wing buds of the limbless mutant are mainly dorsalized.

Importantly, implantation of FGF10-beads into neck LPM did not induce any wing bud structure in the neck (Lours & Dietrich, 2005). Neck wing buds can only be induced by ectopic expression of HoxPG6/7 genes, as reported in the present study. This indicates that the emergence of ectopic limb buds from the neck requires re-specification of Hox code in the neck LPM. Despite the rudimentary outgrowth of the wing buds induced by ectopic HoxPG6/7 expression in the neck region, our experiments demonstrate the pivotal role of HoxPG6/7 in initiating the forelimb-forming program.

PG4/5 are insufficient for forelimb formation

Although both PG4/5 and PG6/7 Hox genes impinge on Tbx5 expression, they play different role during forelimb formation. In contrast to HoxPG6/7, neither the physiological expression of HoxPG4/5 nor their overexpression in the neck region caused Tbx5 expression and initiated formation of an ectopic wing bud. The distinct function of these two groups of Hox genes may be related to their expression pattern. The expression of PG4/5 genes extends beyond the anterior border of the presumptive limb field and some of them are expressed in the entire neck region (http://geisha.arizona.edu). Accordingly, Tbx5 is transiently activated in the entire neck region (Nishimoto et al., 2014). Yet this transient activation is inadequate to initiate forelimb formation, as normally no limbs originate from the neck region. It is only in the limb field where PG4/5 expression overlaps with expression of PG6/7 genes, that Tbx5 expression is maintained and thus can initiate wing formation. Caudal to the forelimb region, this combinatorial effect is limited by Hox9 expression (Cohn et al., 1997; Nishimoto & Logan, 2016; Tanaka, 2016). Functionally, PG4/5 Hox genes can activate Tbx5 expression, but only the mesoderm expressing both PG4/5 and PG6/7 Hox genes can form forelimb. Similar findings have been observed in the specification of motor neurons for the forelimb skeletal muscles (Mukaigasa et al., 2017). The early forelimb motor neuron programme starts in the entire neck region, but only motor neurons under the control of Hox4/5 and Hoxc6 complete their differentiation. Neurons solely under the control of Hox4/5 undergo apoptosis.

Redundancy of limb-forming Hox genes

The partial reduction of wing development seen after dominant-negative form expression with downstream action of any of the Hoxa4/5/6/7 genes is fully consistent with the partial redundancy among Hox paralog groups described for HoxPG5 and HoxPG6 during axial patterning (McIntyre et al., 2007) and HoxPG5 in limb development (Xu et al., 2013). We note, though that we cannot formally exclude incomplete blockade of the genes targeted given the competitive nature of our approach. Be that as it may, our Hox-inactivation experiments clearly reveal a dosage effect of Hox genes on orthologous limb development. They further lead to the conclusion that normal wing development may depend on the balanced expression of HoxPG4/5/6/7 genes.

Permissive and instructive mechanisms during limb evolution

It has been hypothesized that an interplay between permissive, instructive and inhibitory mechanisms is needed to induce precise tissue organization (Morales et al., 2021). Such an interplay may also regulate limb positioning. As shown by several authors, the caudal boundary of the forelimb is determined through the antagonism of the rostral and caudal codes: the rostral code induces forelimb formation, whereas the caudal code inhibits it (Cohn et al., 1997; Moreau et al., 2019; Nishimoto & Logan, 2016; Nishimoto et al., 2014; Tanaka, 2016). In the present study, we suggest that the rostral code should comprise two functionally distinct subgroups. Our data show that inhibiting HoxPG4/5 disrupts limb formation, indicating its necessity. However, overexpressing HoxPG4/5 alone does not induce limb formation, suggesting they are not sufficient. In contrast, HoxPG6/7 is both necessary and sufficient, as their inhibition prevents limb formation and their overexpression induces limb formation.

Thus, we speculate that HoxPG4/5 set up a permissive environment by initiating transient Tbx5 expression that allows limb formation to occur but does not directly trigger the process. The broad expression domain of HoxPG4/5, including the neck region, defines an extended permissive region where forelimb formation might be initiated. In contrast, HoxPG6/7 instructively directs the formation of limbs by maintaining Tbx5 expression in a precise position. The overlap of HoxPG6/7 expression domains with the limb field further supports instructive roles of these Hox genes.

Moreover, the extended Tbx5 expression domain from the heart to forelimb signifies the posterior shift of the forelimb (Anderson et al., 2016) (Fig. 4). As the forelimb programme proceeds, Tbx5 expression is maintained in only the heart and the prospective forelimb region (Fig. 4). Notably, the regression of Tbx5 in the neck region between the heart and forelimb region implies functional differences between PG4/5 and PG6/7 genes.

Permissive, instructive, and inhibitory *Hox* codes regulate the forelimb positioning.
The phylogenetic tree of gnathostomes (A, redrawn from Hirasawa et al., 2016) show that despite the variation in the number of cervical vertebrae (C.V.), the pectoral fin and forelimb (dark blue) are always located at the cervical–thoracic boundary. However, their axial positions with respect to somite number vary widely across species (B and C modified from Burke, 1995). **B, C**: Bright circles: numbered somites; grey shaded circles: thoracic somites; black bars: spinal nerves of the brachial plexus; curved lines: limb bud. In lamprey embryos **(D),** expression of *Tbx5* homologue is restricted to the heart region (Adachi et al., 2016). In skate embryos (E), *Tbx5* expression (blue) extended slightly caudally from the heart anlage (Adachi et al. 2016). In avian embryos (F), it extends from the heart over the neck to the wing field. During wing bud formation, *Tbx5* expression is restricted to only the heart and the wing bud. In lateral plate mesoderm, *Hox4/5* expression (yellow) extends into the neck region, whereas the anterior expression domain of *Hox6/7* (green) is at the wing level. *Hox9* expression (magenta) starts posteriorly to the wing. The yellow, green, and magenta colours represent permissive, instructive, and inhibitory functions, respectively. The blue curved line outlines the wing bud.

There is an evolutionarily conserved requirement for spatial and temporal regulation of cell behaviour during morphogenesis. Hox codes control the growth and shape of almost all organs and the body as a whole. Therefore, the identified mechanisms by which the Hox code genes play permissive and instructive roles in controlling cell behaviour are of general significance for organogenesis during embryonic development and adult regeneration and may elucidate the regional specification mechanisms for other organs.

Towards an evolutionary perspective of vertebral morphology and limb positioning

While the length of the cervical spinal column and the position of the forelimbs are highly fixed in mammals, they are much more variable in other vertebrates, especially from an evolutionary perspective. Indeed, there appears to be an evolutionary trend toward increased head mobility, achieved through the increasing complexity and length of the cervical spine. This trend involves, or presupposes, a caudal repositioning of the anterior limbs.

Extant jawless vertebrates such as lampreys and hagfish lack any morphological vestige suggesting an anlage of anterior limbs. In these species, the expression of Tbx4/5, the hallmark marker of incipient anterior limb and heart development, is restricted to the latter (Adachi, 2016) (Fig. 4D). The first pectoral fins, defined by the presence of a possibly gill-arch-derived pectoral girdle (Janvier, 1996) and connected to the head shield, are found in fossil osteostracans, an early class of gnathostomes (Coates, 1994) (Fig. 4A).

The separation of the pectoral girdle from the head shield resulted in the development of a primary neck, first identifiable in placoderms (Trinajstic et al., 2013) (Fig. 4A). In jawed fish with paired fins, the evolutionary caudal repositioning of the anterior pectoral fins can also be verified by the fact that the expression of Tbx5 is now slightly caudal to the heart anlage (Anderson et al., 2016). This has been documented in skates as well as zebrafish (Adachi et al., 2016; Criswell et al., 2021) (Fig. 4E).

A true neck connecting the cranium and trunk first evolved in amphibians—the first land vertebrates—as the pectoral girdle shifted caudally and the first trunk vertebra transformed into a cervical vertebra (Torrey, 1978) (Fig. 4A, B). With the further evolution of land vertebrates, the number of cervical vertebrae increased significantly (Goodrich, 1906). The longest cervical vertebral columns, with 76 segments, have been reported in the fossil diapsids Muraenosaurus and Elasmosaur Albertonectes (Kubo et al., 2012; Young, 1981). In birds, the number of cervical vertebrae varies widely, ranging from nine to twenty-five (Yapp & Lyons, 1965) (Fig. 4A, C, E). The evolutionarily retained muscular connection between the head and shoulder girdle, formed by the cucullaris muscle and its derivatives, validates this history (Sefton et al., 2016; Theis et al., 2010).

The significance of Hox genes in vertebrate diversification and limb complexity has been repeatedly documented (Cohn & Tickle, 1999; Wellik & Capecchi, 2003; Li et al., 2023; Korth & Polly, 2023). The present results refine our understanding of how Hox genes integrate vertebral column structure and limb positioning, which together have led to the extensive behavior and foraging/predatory diversification of vertebrates (Rytel et al., 2024; Marek et al., 2021).

Materials and Methods

In ovo electroporation

Fertilised chicken (Gallus gallus domesticus) eggs were obtained from the Institute of Animal Sciences of the Agricultural Faculty, University of Bonn, Germany. First, after windowing of the egg shell and exposing the embryo, a solution containing 5–10 µg/µL plasmid and 0.1 % Fast Green was injected into the coelom at specific axial levels. Electroporation was then performed using the CUY 21-Edit-II electroporator with one poration pulse of high voltage (0.01 ms, 70 V) followed by two driving pulses of low voltage (50 ms, 7 V, with 200 ms intervals). There is a 99.9 ms interval between the high and low voltage pulses. After reincubation, embryos were imaged under the Nikon SM21500 fluorescence microscope and then fixed in 4 % paraformaldehyde overnight at 4°C.

Plasmids for electroporation

DNA plasmids were produced by Dongze Bio-products (Guangzhou, China). Coding sequences (obtained from NCBI) for Hoxa4 (930bp, NM_001030346.3), Hoxa5 (813bp, NM_001318419.2), Hoxa6 (696bp, NM_001030987.4), Hoxb6 (669bp, NM_001396636.1), Hoxc6 (714bp, NM_001407494.1), Hoxa7 (660bp, NM_204595.3) or Hoxb7 (654bp, XM_040653307.2) were inserted into the pCAGGS-P2A-EGFP plasmid. A plasmid expressing the dominant negative (dn) form specific for Hoxa4, a5, a6 or a7 was produced using their coding sequence lacking the C-terminal portion, including Hoxa4dn (762bp), Hoxa5dn (729bp), Hoxa6dn (585bp) and Hoxa7dn (528bp). A large quantity of DNA plasmids was purified using the NucleoBond Xtra Midi DNA preparation kit (MACHEREY-NAGEL).

RNA in situ hybridisation

Whole-mount RNA in situ hybridization was performed by incubating probes at 65°C (Nieto, Patel et al. 1996). The probes were detected using anti-Digoxigenin-AP, fab fragments (Roche) and color reagent NBT/BCIP staining solution (Roche). Chicken Lmx-1, Fgf10 and Fgf8 probes were provided by H. Ohuchi, O. Pourquie and C. Tabin, respectively. Chicken Tbx5 probe, Hox probes and Hoxdn C-terminal probes were produced using PCR and transcribed using the DIG-RNA Labelling Kit (Roche, #11175025910) with T7 polymerase. The specific primers were shown in Table 4.

Primer sequences used for generating in situ hybridization probes by PCR.

RNA-Seq analyses

Wing parts (five samples per replicate, four replicates, total 20 samples) and neck parts (20 samples per replicate, four replicates, total 80 samples) were dissected from HH22 normal embryos. Additionally, a total of 80 Hoxa6-induced ectopic buds (20 samples per replicate, four replicates) were dissected from HH22 embryos with Hoxa6 ectopic expression in the neck. The dissections were performed under the Nikon SM21500 fluorescence microscope. Only ectopic buds identified by their morphology and EGFP expression were isolated and collected, including the surface ectoderm. Total RNA of samples was isolated with miRNeasy Micro Kit (QIAGEN). Library preparation was performed according to the manufacturer’s protocol using the ‘VAHT Universal RNA-Seq Library Prep Kit for Illumina V6 with mRNA capture module’. Next, 500 ng total RNA was used for mRNA capturing, fragmentation, cDNA synthesis, adapter ligation and library amplification. Bead-purified libraries were normalised and finally sequenced on the HiSeq 3000/4000 system (Illumina Inc. San Diego, USA).

Statistical analysis

Data analyses on FASTQ files were conducted with CLC Genomics Workbench (version 21.0.4, QIAGEN, Venlo. NL). The reads of all probes were adapter trimmed (Illumina TruSeq) and quality trimmed. Mapping was done against the Gallus gallus (GRCg6a) (19 March, 2021) genome sequence. Statistically significant differential expression was determined using the ‘Differential Expression for RNA-Seq’ tool (version 2.4) (Qiagen Inc. 2021). The resulting P values were corrected for multiple testing by FDR. The RNA expression level was indicated by reads per kilobase of transcript per million mapped reads (RPKM) and the statistical analysis between the three groups were made by ordinary one-way ANOVA, using GraphPad Prism v6 (San Diego, CA, USA). Functional annotation clustering was done by means of the DAVID online tool (https://david.ncifcrf.gov/) and using the Gene Ontology “biological process” annotation category. Data are presented as mean ± standard error of the mean. The level of statistical significance was set at **p < 0.01.

Competing Interest Statement

The authors declare no competing interests.

Acknowledgements

The authors thank Sandra Graefe and Heinz Bioernsen for their expert technical assistance. Computational support from the Centre for Information and Media Technology, especially the High-Performance Computing team at Heinrich-Heine University, is acknowledged. This work was supported by grants from China Scholarship Council (CSC) and by German Research Funding (DFG-Hu 729/13).

Author Contributions

Conceptualisation: YW, RH, KP, MH, TB, SK, QP. Investigation: YW. Methodology: YW, JBW, LC, JLW, PZ, HT, ZL, XQ, DC. RNA-Seq: PP, KK, YW. Funding acquisition: YW, SK, RH. Writing: YW, RH, KS, MH, KP, SK, QP, JW, GK.

References

1.
1. Adachi N.
2. Robinson M.
3. Goolsbee A.
4. Shubin N. H
2016Regulatory evolution of Tbx5 and the origin of paired appendagesProc Natl Acad Sci U S A 113:10115–10120https://doi.org/10.1073/pnas.1609997113
2.
1. Anderson C.
2. Khan M. A. F.
3. Wong F.
4. Solovieva T.
5. Oliveira N. M. M.
6. Baldock R. A.
7. Stern C. D.
2016A strategy to discover new organizers identifies a putative heart organizerNat Commun 7https://doi.org/10.1038/ncomms12656
3.
1. Barrow J. R.
2. Thomas K. R.
3. Boussadia-Zahui O.
4. Moore R.
5. Kemler R.
6. Capecchi M. R.
7. McMahon A. P
2003Ectodermal Wnt3/beta-catenin signaling is required for the establishment and maintenance of the apical ectodermal ridgeGenes Dev 17:394–409https://doi.org/10.1101/gad.1044903
4.
1. Becker D.
2. Eid R.
3. Schughart K
1996The limb/LPM enhancer of the murine Hoxb6 gene: reporter gene analysis in transgenic embryos and studies of DNA-protein interactionsPharm Acta Helv 71:29–35https://doi.org/10.1016/0031-6865(95)00049-6
5.
1. Becker D.
2. Jiang Z.
3. Knödler P.
4. Deinard A. S.
5. Eid R.
6. Kidd K. K.
7. Schughart K.
1996Conserved regulatory element involved in the early onset of Hoxb6 gene expressionDev Dyn 205:73–81https://doi.org/10.1002/(sici)1097-0177(199601)205:1<73::Aid-aja7>3.0.Co;2-2
6.
1. Böhmer C
2017Correlation between Hox code and vertebral morphology in the mouse: towards a universal model for SynapsidaZoological Lett 3https://doi.org/10.1186/s40851-017-0069-4
7.
1. Burke A. C
2000Hox genes and the global patterning of the somitic mesodermCurr Top Dev Biol 47:155–181
8.
1. Burke A. C.
2. Nelson C. E.
3. Morgan B. A.
4. Tabin C
1995Hox genes and the evolution of vertebrate axial morphologyDevelopment 121:333–346
9.
1. Chaube S
1959On axiation and symmetry in transplanted wing of the chickJournal of Experimental Zoology 140:29–77
10.
1. Coates M. I
1994The origin of vertebrate limbsDev Suppl :169–180
11.
1. Cohn M. J.
2. Izpisúa-Belmonte J. C.
3. Abud H.
4. Heath J. K.
5. Tickle C
1995Fibroblast growth factors induce additional limb development from the flank of chick embryosCell 80:739–746https://doi.org/10.1016/0092-8674(95)90352-6
12.
1. Cohn M. J.
2. Patel K.
3. Krumlauf R.
4. Wilkinson D. G.
5. Clarke J. D.
6. Tickle C
1997Hox9 genes and vertebrate limb specificationNature 387:97–101https://doi.org/10.1038/387097a0
13.
1. Cohn M. J.
2. Tickle C.
1999Developmental basis of limblessness and axial patterning in snakesNature 399:474–479https://doi.org/10.1038/20944
14.
1. Criswell K. E.
2. Roberts L. E.
3. Koo E. T.
4. Head J. J.
5. Gillis J. A
2021hox gene expression predicts tetrapod-like axial regionalization in the skate, Leucoraja erinaceaProc Natl Acad Sci U S A 118https://doi.org/10.1073/pnas.2114563118
15.
1. Crossley P. H.
2. Minowada G.
3. MacArthur C. A.
4. Martin G. R
1996Roles for FGF8 in the induction, initiation, and maintenance of chick limb developmentCell 84:127–136https://doi.org/10.1016/s0092-8674(00)80999-x
16.
1. Delgado I.
2. Giovinazzo G.
3. Temiño S.
4. Gauthier Y.
5. Balsalobre A.
6. Drouin J.
7. Torres M
2021Control of mouse limb initiation and antero-posterior patterning by Meis transcription factorsNat Commun 12https://doi.org/10.1038/s41467-021-23373-9
17.
1. Denans N.
2. Iimura T.
3. Pourquié O
2015Hox genes control vertebrate body elongation by collinear Wnt repressionElife 4https://doi.org/10.7554/eLife.04379
18.
1. Duboule D
2022The (unusual) heuristic value of Hox gene clusters; a matter of time?Dev Biol 484:75–87https://doi.org/10.1016/j.ydbio.2022.02.007
19.
1. Duboule D.
2. Dollé P
1989The structural and functional organization of the murine HOX gene family resembles that of Drosophila homeotic genesEMBO J 8:1497–1505
20.
1. Fernandez-Guerrero M.
2. Zdral S.
3. Castilla-Ibeas A.
4. Lopez-Delisle L.
5. Duboule D.
6. Ros M. A
2022Time-sequenced transcriptomes of developing distal mouse limb buds: A comparative tissue layer analysisDev Dyn 251:1550–1575https://doi.org/10.1002/dvdy.394
21.
1. Garcia-Gasca A.
2. Spyropoulos D. D.
2000Differential mammary morphogenesis along the anteroposterior axis in Hoxc6 gene targeted miceDevelopmental dynamics: an official publication of the American Association of Anatomists 219:261–276
22.
1. Gehring W. J.
2. Müller M.
3. Affolter M.
4. Percival-Smith A.
5. Billeter M.
6. Qian Y. Q.
7. Wüthrich K
1990The structure of the homeodomain and its functional implicationsTrends Genet 6:323–329https://doi.org/10.1016/0168-9525(90)90253-3
23.
1. Goodrich E. S
1906Memoirs: Notes on the development, structure, and origin of the median and paired fins of fishJournal of Cell Science 2:333–376
24.
1. Grieshammer U.
2. Minowada G.
3. Pisenti J. M.
4. Abbott U. K.
5. Martin G. R
1996The chick limbless mutation causes abnormalities in limb bud dorsal-ventral patterning: implications for the mechanism of apical ridge formationDevelopment 122:3851–3861
25.
1. Gros J.
2. Tabin C. J
2014Vertebrate limb bud formation is initiated by localized epithelial-to-mesenchymal transitionScience 343:1253–1256https://doi.org/10.1126/science.1248228
26.
1. Hamburger V.
2. Hamilton H. L
1951A series of normal stages in the development of the chick embryoJournal of morphology 88:49–92
27.
1. Hasson P.
2. Del Buono J.
3. Logan M. P
2007Tbx5 is dispensable for forelimb outgrowthDevelopment 134:85–92https://doi.org/10.1242/dev.02622
28.
1. Horan G.
2. Ramírez-Solis R.
3. Featherstone M. S.
4. Wolgemuth D. J.
5. Bradley A.
6. Behringer R. R
1995Compound mutants for the paralogous hoxa-4, hoxb-4, and hoxd-4 genes show more complete homeotic transformations and a dose-dependent increase in the number of vertebrae transformedGenes & development 9:1667–1677
29.
1. Horan G.
2. Wu K.
3. Wolgemuth D. J.
4. Behringer R. R
1994Homeotic transformation of cervical vertebrae in Hoxa-4 mutant miceProceedings of the National Academy of Sciences 91:12644–12648
30.
1. Horan G. S.
2. Kovàcs E. N.
3. Behringer R. R.
4. Featherstone M. S
1995Mutations in paralogous Hox genes result in overlapping homeotic transformations of the axial skeleton: evidence for unique and redundant functionDevelopmental biology 169:359–372
31.
1. Iimura T.
2. Pourquie O
2006Collinear activation of Hoxb genes during gastrulation is linked to mesoderm cell ingressionNature 442:568–571https://doi.org/10.1038/nature04838
32.
1. Janvier P
1996Early vertebratesOxford Univ. Press
33.
1. Jeannotte L.
2. Lemieux M.
3. Charron J.
4. Poirier F.
5. Robertson E
1993Specification of axial identity in the mouse: role of the Hoxa-5 (Hox1. 3) geneGenes & development 7:2085–2096
34.
1. Kessel M.
2. Gruss P
1991Homeotic transformations of murine vertebrae and concomitant alteration of Hox codes induced by retinoic acidCell 67:89–104https://doi.org/10.1016/0092-8674(91)90574-i
35.
1. Kort A. E.
2. Polly P. D
2023Allometry then locomotor diversification shaped the evolution of lumbar morphology in early placental mammalsEvolutionary Journal of the Linnean Society 2
36.
1. Kubo T.
2. Mitchell M. T.
3. Henderson D. M
2012Albertonectes vanderveldei, a new elasmosaur (Reptilia, Sauropterygia) from the Upper Cretaceous of AlbertaJournal of Vertebrate Paleontology 32:557–572
37.
1. Lin G. H.
2. Zhang L
2020Apical ectodermal ridge regulates three principal axes of the developing limbJ Zhejiang Univ Sci B 21:757–766https://doi.org/10.1631/jzus.B2000285
38.
1. Li Y.
2. Brinkworth A.
3. Green E.
4. et al.
2023Divergent vertebral formulae shape the evolution of axial complexity in mammalsNat Ecol Evol 7:367–381
39.
1. Lours C.
2. Dietrich S
2005The dissociation of the Fgf-feedback loop controls the limbless state of the neckDevelopment 132:5553–5564https://doi.org/10.1242/dev.02164
40.
1. Marek RD
2. Falkingham PL
3. Benson RBJ
4. Gardiner JD
5. Maddox TW
6. Bates KT
2021Evolutionary versatility of the avian neckProc. R. Soc. B 288
41.
1. McIntyre D. C.
2. Rakshit S.
3. Yallowitz A. R.
4. Loken L.
5. Jeannotte L.
6. Capecchi M. R.
7. Wellik D. M
2007Hox patterning of the vertebrate rib cageDevelopment 134:2981–2989https://doi.org/10.1242/dev.007567
42.
1. Min H.
2. Danilenko D. M.
3. Scully S. A.
4. Bolon B.
5. Ring B. D.
6. Tarpley J. E.
7. Simonet W. S.
1998Fgf-10 is required for both limb and lung development and exhibits striking functional similarity to Drosophila branchlessGenes Dev 12:3156–3161https://doi.org/10.1101/gad.12.20.3156
43.
1. Minguillon C.
2. Nishimoto S.
3. Wood S.
4. Vendrell E.
5. Gibson-Brown J. J.
6. Logan M. P
2012Hox genes regulate the onset of Tbx5 expression in the forelimbDevelopment 139:3180–3188https://doi.org/10.1242/dev.084814
44.
1. Morales J. S.
2. Raspopovic J.
3. Marcon L
2021From embryos to embryoids: How external signals and self-organization drive embryonic developmentStem Cell Reports 16:1039–1050https://doi.org/10.1016/j.stemcr.2021.03.026
45.
1. Moreau C.
2. Caldarelli P.
3. Rocancourt D.
4. Roussel J.
5. Denans N.
6. Pourquie O.
7. Gros J
2019Timed Collinear Activation of Hox Genes during Gastrulation Controls the Avian Forelimb PositionCurr Biol 29:35–50https://doi.org/10.1016/j.cub.2018.11.009
46.
1. Mukaigasa K.
2. Sakuma C.
3. Okada T.
4. Homma S.
5. Shimada T.
6. Nishiyama K.
7. Yaginuma H
2017Motor neurons with limb-innervating character in the cervical spinal cord are sculpted by apoptosis based on the Hox code in chick embryoDevelopment 144:4645–4657
47.
1. Nishimoto S.
2. Logan M. P
2016Subdivision of the lateral plate mesoderm and specification of the forelimb and hindlimb forming domainsSemin Cell Dev Biol 49:102–108https://doi.org/10.1016/j.semcdb.2015.11.011
48.
1. Nishimoto S.
2. Minguillon C.
3. Wood S.
4. Logan M. P
2014A combination of activation and repression by a colinear Hox code controls forelimb-restricted expression of Tbx5 and reveals Hox protein specificityPLoS Genet 10https://doi.org/10.1371/journal.pgen.1004245
49.
1. Nishimoto S.
2. Wilde S. M.
3. Wood S.
4. Logan M. P
2015RA Acts in a Coherent Feed-Forward Mechanism with Tbx5 to Control Limb Bud Induction and InitiationCell Rep 12:879–891https://doi.org/10.1016/j.celrep.2015.06.068
50.
1. Rallis C.
2. Bruneau B. G.
3. Del Buono J.
4. Seidman C. E.
5. Seidman J. G.
6. Nissim S.
7. Logan M. P.
2003Tbx5 is required for forelimb bud formation and continued outgrowthDevelopment 130:2741–2751https://doi.org/10.1242/dev.00473
51.
1. Ramfrez-Solis R.
2. Zheng H.
3. Whiting J.
4. Krumlauf R.
5. Bradley A
1993Hoxb-4 (Hox-2.6) mutant mice show homeotic transformation of a cervical vertebra and defects in the closure of the sternal rudimentsCell 73:279–294
52.
1. Rancourt D. E.
2. Tsuzuki T.
3. Capecchi M. R
1995Genetic interaction between hoxb-5 and hoxb-6 is revealed by nonallelic noncomplementationGenes & development 9:108–122
53.
1. Ros M. A.
2. López-Martínez A.
3. Simandl B. K.
4. Rodriguez C.
5. Izpisua Belmonte J.
6. Dahn R.
7. Fallon J. F
1996The limb field mesoderm determines initial limb bud anteroposterior asymmetry and budding independent of sonic hedgehog or apical ectodermal gene expressionsDevelopment 122:2319–2330
54.
1. Rytel A
2. Böhmer C
3. Spiekman SNF
4. Tałanda M
2024Extreme neck elongation evolved despite strong developmental constraints in bizarre Triassic reptiles—implications for neck modularity in archosaursR. Soc. Open Sci 11
55.
1. Sefton E. M.
2. Bhullar B. A.
3. Mohaddes Z.
4. Hanken J
2016Evolution of the head-trunk interface in tetrapod vertebratesElife 5https://doi.org/10.7554/eLife.09972
56.
1. Sekine K.
2. Ohuchi H.
3. Fujiwara M.
4. Yamasaki M.
5. Yoshizawa T.
6. Sato T.
7. Kato S.
1999Fgf10 is essential for limb and lung formationNat Genet 21:138–141https://doi.org/10.1038/5096
57.
1. Steimle J.
2. Moskowitz I
2017TBX5: a key regulator of heart developmentCurr Top Dev Biol 122:195–221
58.
1. Tanaka M
2016Developmental Mechanism of Limb Field Specification along the Anterior-Posterior Axis during Vertebrate EvolutionJ Dev Biol 4https://doi.org/10.3390/jdb4020018
59.
1. Takeuchi J. K.
2. Koshiba-Takeuchi K.
3. Suzuki T.
4. Kamimura M.
5. Ogura K.
6. Ogura T
2003Tbx5 and Tbx4 trigger limb initiation through activation of the Wnt/Fgf signaling cascadeDevelopment 130:2729–2739https://doi.org/10.1242/dev.00474
60.
1. Theis S.
2. Patel K.
3. Valasek P.
4. Otto A.
5. Pu Q.
6. Harel I.
7. Huang R
2010The occipital lateral plate mesoderm is a novel source for vertebrate neck musculatureDevelopment 137:2961–2971https://doi.org/10.1242/dev.049726
61.
1. Tickle C
2002Molecular basis of vertebrate limb patterningAmerican journal of medical genetics 112:250–255
62.
1. Torrey T
1978Morphogenesis of the Vertebrates New YorkIn: Wiley
63.
1. Trinajstic K.
2. Sanchez S.
3. Dupret V.
4. Tafforeau P.
5. Long J.
6. Young G.
7. Ahlberg P. E.
2013Fossil musculature of the most primitive jawed vertebratesScience 341:160–164https://doi.org/10.1126/science.1237275
64.
1. Vogel A.
2. Rodriguez C.
3. Izpisúa-Belmonte J.-C
1996Involvement of FGF-8 in initiation, outgrowth and patterning of the vertebrate limbDevelopment 122:1737–1750
65.
1. Xu B.
2. Hrycaj S. M.
3. McIntyre D. C.
4. Baker N. C.
5. Takeuchi J. K.
6. Jeannotte L.
7. Wellik D. M
2013Hox5 interacts with Plzf to restrict Shh expression in the developing forelimbProc Natl Acad Sci U S A 110:19438–19443https://doi.org/10.1073/pnas.1315075110
66.
1. Yapp W. B.
2. Lyons K. M
1965Vertebrates: Their structure and lifeOxford Univ. Press
67.
1. Yin W.
2. Wang Z. J.
3. Li Q. Y.
4. Lian J. M.
5. Zhou Y.
6. Lu B. Z.
7. Zhou Q
2016Evolutionary trajectories of snake genes and genomes revealed by comparative analyses of five-pacer viperNat Commun 7https://doi.org/10.1038/ncomms13107
68.
1. Young J. J.
2. Grayson P.
3. Edwards S. V.
4. Tabin C. J
2019Attenuated Fgf Signaling Underlies the Forelimb Heterochrony in the Emu Dromaius novaehollandiaeCurr Biol 29:3681–3691https://doi.org/10.1016/j.cub.2019.09.014
69.
1. Zakany J.
2. Duboule D
2007The role of Hox genes during vertebrate limb developmentCurrent opinion in genetics & development 17:359–366

Article and author information

Author information

Yajun Wang
Institute of Neuroanatomy, University of Bonn, Medical Faculty, Bonn, Germany
ORCID iD: 0009-0004-6955-0454
- For correspondence: yajun0809@163.com
Maik Hintze
Institute of Neuroanatomy, University of Bonn, Medical Faculty, Bonn, Germany
Jinbao Wang
Institute of Neuroanatomy, University of Bonn, Medical Faculty, Bonn, Germany, School of Basic Medical Sciences, Ningxia Medical University, Yinchuan, China
Patrick Petzsch
Biological and Medical Research Centre (BMFZ), Medical Faculty, Heinrich-Heine-University Duesseldorf, Duesseldorf, Germany
ORCID iD: 0000-0002-8355-5524
Karl Köhrer
Biological and Medical Research Centre (BMFZ), Medical Faculty, Heinrich-Heine-University Duesseldorf, Duesseldorf, Germany
Hengxun Tao
Institute of Neuroanatomy, University of Bonn, Medical Faculty, Bonn, Germany
Longfei Cheng
Institute of Neuroanatomy, University of Bonn, Medical Faculty, Bonn, Germany
Peng Zhou
Institute of Neuroanatomy, University of Bonn, Medical Faculty, Bonn, Germany, Institute of Zoology, School of Life Sciences, Lanzhou University, Lanzhou, China
Jianlin Wang
College of Pastoral Agriculture Science and Technology, Lanzhou University, Lanzhou, China
Zhaofu Liao
Key Laboratory of Regenerative Medicine, Ministry of Education, Department of Developmental & Regenerative Biology, Jinan University, Guangzhou, China
Xufeng Qi
Key Laboratory of Regenerative Medicine, Ministry of Education, Department of Developmental & Regenerative Biology, Jinan University, Guangzhou, China
ORCID iD: 0000-0002-5911-071X
Dongqing Cai
Key Laboratory of Regenerative Medicine, Ministry of Education, Department of Developmental & Regenerative Biology, Jinan University, Guangzhou, China
Thomas Bartolomaeus
Institute of Evolutionary Biology and Animal Ecology, Rheinische Friedrich-Wilhelms-Universität, Bonn, Germany
Karl Schilling
Institute of Anatomy, Department of Cell Biology, University of Bonn, Medical Faculty, Bonn, Germany
Joerg Wilting
Deparment of Anatomy and Cell Biology, University Medical School Goettingen, Goettingen, Germany
Stefanie Kuerten
Institute of Neuroanatomy, University of Bonn, Medical Faculty, Bonn, Germany, University Hospital Bonn, Bonn, 53127, Germany
Georgy Koentges
Laboratory of Systems Biomedicine and Evolution, School of Life Sciences, University of Warwick, UK
Ketan Patel
School of Biological Sciences, University of Reading, Reading, UK
ORCID iD: 0000-0002-7131-749X
Qin Pu
Institute of Neuroanatomy, University of Bonn, Medical Faculty, Bonn, Germany
Ruijin Huang
Institute of Neuroanatomy, University of Bonn, Medical Faculty, Bonn, Germany, University Hospital Bonn, Bonn, 53127, Germany
- For correspondence: ruijin.huang@uni-bonn.de

Version history

Sent for peer review: July 14, 2024
Preprint posted: July 19, 2024
Reviewed Preprint version 1: October 14, 2024

Copyright

This article is distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use and redistribution provided that the original author and source are credited.

Metrics

views: 127
downloads: 3
citations: 0

Views, downloads and citations are aggregated across all versions of this paper published by eLife.

Significance of findings

Strength of evidence

Abstract

Impact statement

Classification

Introduction

Results

HoxPG4–7 are required for the forelimb formation

Hoxa4/a5/a6/a7 genes are necessary for wing bud formation.

Dominant negative expression of Hoxa4/a5/a6/a7 down-regulated gene expression.

Hox6/7 but not Hox4/5 are sufficient to reprogram neck to wing mesoderm

Hoxa6/a7 but not Hoxa4/a5 are sufficient to induce a neck wing bud.

HoxPG6/7 upregulated wing bud formation in the neck region.

The neck wing bud is smaller than the natural wing bud.

Gene Ontology analyses showing top ten terms in Biological Process.

Discussion

PG4/5/6/7 genes constitute the Hox code activating forelimb formation

PG6/7 genes are sufficient for forelimb formation

PG4/5 are insufficient for forelimb formation

Redundancy of limb-forming Hox genes

Permissive and instructive mechanisms during limb evolution

Permissive, instructive, and inhibitory Hox codes regulate the forelimb positioning.

Towards an evolutionary perspective of vertebral morphology and limb positioning

Materials and Methods

In ovo electroporation

Plasmids for electroporation

RNA in situ hybridisation

RNA-Seq analyses

Statistical analysis

Competing Interest Statement

Acknowledgements

Author Contributions

References

Article and author information

Author information

Yajun Wang

Maik Hintze

Jinbao Wang

Patrick Petzsch

Karl Köhrer

Hengxun Tao

Longfei Cheng

Peng Zhou

Jianlin Wang

Zhaofu Liao

Xufeng Qi

Dongqing Cai

Thomas Bartolomaeus

Karl Schilling

Joerg Wilting

Stefanie Kuerten

Georgy Koentges

Ketan Patel

Qin Pu

Ruijin Huang

Version history

Copyright

Metrics