Expanded HOXA13 polyalanine tracts in a monotreme

The N-terminal region of human HOXA13 has seven discrete polyalanine tracts. Our previous analysis of these tracts in multiple major vertebrate clades suggested that three are mammal-specific. We now report the N-terminal HOXA13 repetitive tract structures in the monotreme Tachyglossus aculeatus (echidna). Contrary to our expectations, echidna HOXA13 possesses a unique set of polyalanine tracts and an unprecedented polyglycine tract. The data support the conclusion that the emergence of expanded polyalanine tracts in proteins occurred very early in the stem lineage that gave rise to mammals, between 162 and 315 Ma.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/73357/1/j.1525-142X.2008.00254.x.pd

Hox11 Function Is Required for Region‐Specific Fracture Repair

The processes that govern fracture repair rely on many mechanisms that recapitulate embryonic skeletal development. Hox genes are transcription factors that perform critical patterning functions in regional domains along the axial and limb skeleton during development. Much less is known about roles for these genes in the adult skeleton. We recently reported that Hox11 genes, which function in zeugopod development (radius/ulna and tibia/fibula), are also expressed in the adult zeugopod skeleton exclusively in PDGFRα+/CD51+/LepR+ mesenchymal stem/stromal cells (MSCs). In this study, we use a Hoxa11eGFP reporter allele and loss‐of‐function Hox11 alleles, and we show that Hox11 expression expands after zeugopod fracture injury, and that loss of Hox11 function results in defects in endochondral ossification and in the bone remodeling phase of repair. In Hox11 compound mutant fractures, early chondrocytes are specified but show defects in differentiation, leading to an overall deficit in the cartilage production. In the later stages of the repair process, the hard callus remains incompletely remodeled in mutants due, at least in part, to abnormal bone matrix organization. Overall, our data supports multiple roles for Hox11 genes following fracture injury in the adult skeleton. © 2017 American Society for Bone and Mineral Research.Peer Reviewedhttps://deepblue.lib.umich.edu/bitstream/2027.42/138416/1/jbmr3166_am.pdfhttps://deepblue.lib.umich.edu/bitstream/2027.42/138416/2/jbmr3166.pd

BAC transgenic analysis reveals enhancers sufficient for Hoxa13 and neighborhood gene expression in mouse embryonic distal limbs and genital bud

We previously demonstrated that a ∼1 Mb domain of genes upstream of and including Hoxa13 is co-expressed in the developing mouse limbs and genitalia. A highly conserved non-coding sequence, mmA13CNS, was shown to be insufficient in transgenic mice to direct precise Hoxa13 -like expression in the limb buds or genital bud, although some LacZ expression from the transgene was reproducibly found in these tissues. In this report, we used Β -globin minimal promoter LacZ recombinant BAC transgenes encompassing mmA13CNS to identify a single critical region involved in mouse Hoxa13 -like embryonic genital bud expression. By analyzing the expression patterns of these overlapping BAC clones in transgenic mice, we show that at least two sequences remote to the HoxA cluster are required collectively to drive Hoxa13 -like expression in developing distal limbs. Given that the paralogous posterior HoxD and neighboring genes have been shown to be under the influence of long-range distal limb and genital bud enhancers, we hypothesize that both long-range enhancers have one ancestral origin, which diverged in both sequence and function after the HoxA/D cluster duplication.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/73951/1/j.1525-142X.2008.00253.x.pd

Of fingers, toes and penises

Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/62765/1/390029a0.pd

Cell lineage transport: a mechanism for molecular gradient formation

Gradient formation is a fundamental patterning mechanism during embryo development, commonly related to secreted proteins that move along an existing field of cells. Here, we mathematically address the feasibility of gradients of mRNAs and non-secreted proteins. We show that these gradients can arise in growing tissues whereby cells dilute and transport their molecular content as they divide and grow, a mechanism we termed ‘cell lineage transport.' We provide an experimental test by unveiling a distal-to-proximal gradient of Hoxd13 in the vertebrate developing limb bud driven by cell lineage transport, corroborating our model. Our study indicates that gradients of non-secreted molecules exhibit a power-law profile and can arise for a wide range of biologically relevant parameter values. Dilution and nonlinear growth confer robustness to the spatial gradient under changes in the cell cycle period, but at the expense of sensitivity in the timing of gradient formation. We expect that gradient formation driven by cell lineage transport will provide future insights into understanding the coordination between growth and patterning during embryonic development

Generation and expression of a Hoxa11eGFP targeted allele in mice

Hox genes are crucial for body axis specification during embryonic development. Hoxa11 plays a role in anteroposterior patterning of the axial skeleton, development of the urogenital tract of both sexes, and proximodistal patterning of the limbs. Hoxa11 expression is also observed in the neural tube. Herein, we report the generation of a Hoxa11eGFP targeted knock-in allele in mice in which eGFP replaces the first coding exon of Hoxa11 as an in-frame fusion. This allele closely recapitulates the reported mRNA expression patterns for Hoxa11 . Hoxa11eGFP can be visualized in the tail, neural tube, limbs, kidneys, and reproductive tract of both sexes. Additionally, homozygous mutants recapitulate reported phenotypes for Hoxa11 loss of function mice, exhibiting loss of fertility in both males and females. This targeted mouse line will prove useful as a vital marker for Hoxa11 protein localization during control (heterozygous) or mutant organogenesis. Developmental Dynamics 237:3410–3416, 2008. © 2008 Wiley-Liss, Inc.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/61238/1/21756_ftp.pd

Hox11 paralogous genes are required for formation of wrist and ankle joints and articular surface organization

Limb skeletal elements are connected by distinct synovial joints, but the mechanisms regulating joint formation, diversity, and organization remain unclear. Previous studies showed that Hox11 mouse mutants have severe developmental defects in radius and ulna and tibia and fibula, but wrist and ankle joint formation and characteristics were not examined in detail. We now find that E11.5 and E12.5 triple Hox11aaccdd mutants exhibit a significant reduction in prospective carpal and tarsal mesenchyme. Although the mesenchyme became segmented into individual carpal and tarsal skeletal elements with further development, the elements were ill defined and the more proximal elements (radiale, ulnare, talus, and calcaneous) actually underwent involution and/or fusion. Wild-type carpal and tarsal elements displayed a thick articulating superficial zone at their outer perimeter that expressed genes typical of developing joint interzones and articulating cells, including Gdf5 , Erg , Gli3 , collagen IIA, and lubricin, and defined each element anatomically. In mutant wrists and ankles, the superficial zone around each element was thin and ill defined, and expression of several of those genes was low and often interrupted. These and other data provide novel and clear evidence that Hox11 paralogous genes regulate wrist and ankle joint organization and are essential for establishing carpal and tarsal element boundary and maintaining their articulating surface tissue.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/79083/1/j.1749-6632.2009.05234.x.pd

Hoxa cluster genes determine the proliferative activity of adult mouse hematopoietic stem and progenitor cells

Determination of defined roles for endogenous homeobox (Hox) genes in adult hematopoietic stem and progenitor cell (HSPC) activity has been hampered by a combination of embryonic defects and functional redundancy. Here we show that conditional homozygous deletion of the Hoxa cluster (Hoxa−/−) results in a marked reduction of adult HSPC activity, both in vitro and in vivo. Specifically, proliferation of Hoxa−/− HSPCs is reduced compared with wild-type (WT) cells in vitro and they are less competitive in vivo. Notably, the loss of Hoxa genes had little impact on HSPC differentiation. Comparative RNA sequencing analyses of Hoxa−/− and WT hematopoietic stem cells (CD150+/CD48−/Lineage−/c-kit+/Sca-1+) identified a large number of differentially expressed genes, three of which (Nr4a3, Col1a1, and Hnf4a) showed >10-fold reduced levels. Engineered overexpression of Hoxa9 in Hoxa−/− HSPCs resulted in partial phenotypic rescue in vivo with associated recovery in expression of a large proportion of deregulated genes. Together, these results provide definitive evidence linking Hoxa gene expression to proliferation of adult HSPCs

Hox patterning of the vertebrate axial skeleton

The axial skeleton in all vertebrates is composed of similar components that extend from anterior to posterior along the body axis: the occipital skull bones and cervical, thoracic, lumbar, sacral, and caudal vertebrae. Despite significant changes in the number and size of these elements during evolution, the basic character of these anatomical elements, as well as the order in which they appear in vertebrate skeletons, have remained remarkably similar. Through extensive expression analyses, classic morphological perturbation experiments in chicken and targeted loss-of-function analyses in mice, Hox genes have proven to be critical regulators in the establishment of axial skeleton morphology. The convergence of these studies to date allows an emerging understanding of Hox gene function in patterning the vertebrate axial skeleton. This review summarizes genetic and embryologic findings regarding the role of Hox genes in establishing axial morphology and how these combined results impact our current understanding of the vertebrate Hox code. Developmental Dynamics 236:2454–2463, 2007. © 2007 Wiley-Liss, Inc.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/56149/1/21286_ftp.pd