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Homeobox

April 26, 2024

A homeobox is a DNA sequence, around 180 base pairs long, that regulates large-scale anatomical features in the early stages of embryonic development. Mutations in a homeobox may change large-scale anatomical features of the full-grown organism.

Homeodomain
The Antennapedia homeodomain protein from Drosophila melanogaster bound to a fragment of DNA.[1] The recognition helix and unstructured N-terminus are bound in the major and minor grooves respectively.
Identifiers
SymbolHomeodomain
PfamPF00046
Pfam clanCL0123
InterProIPR001356
SMARTSM00389
PROSITEPDOC00027
SCOP21ahd / SCOPe / SUPFAM
Available protein structures:
Pfam  structures / ECOD  
PDBRCSB PDB; PDBe; PDBj
PDBsumstructure summary
PDB1ahd​, 1akh​, 1apl​, 1au7​, 1b72​, 1b8i​, 1bw5​, 1cqt​, 1du0​, 1du6​, 1e3o​, 1enh​, 1f43​, 1fjl​, 1ftt​, 1ftz​, 1gt0​, 1hdd​, 1hdp​, 1hf0​, 1hom​, 1ic8​, 1ig7​, 1jgg​, 1k61​, 1kz2​, 1le8​, 1lfb​, 1lfu​, 1mh3​, 1mh4​, 1mnm​, 1nk2​, 1nk3​, 1o4x​, 1ocp​, 1oct​, 1p7i​, 1p7j​, 1pog​, 1puf​, 1qry​, 1s7e​, 1san​, 1uhs​, 1vnd​, 1wi3​, 1x2m​, 1x2n​, 1yrn​, 1yz8​, 1zq3​, 1ztr​, 2cqx​, 2cra​, 2cue​, 2cuf​, 2dmq​, 2e1o​, 2ecb​, 2ecc​, 2h8r​, 2hdd​, 2hi3​, 2hoa​, 2jwt​, 2lfb​, 2p81​, 2r5y​, 2r5z​, 3hdd​, 9ant

Homeoboxes are found within genes that are involved in the regulation of patterns of anatomical development (morphogenesis) in animals, fungi, plants, and numerous single cell eukaryotes.[2] Homeobox genes encode homeodomain protein products that are transcription factors sharing a characteristic protein fold structure that binds DNA to regulate expression of target genes.[3][4][2] Homeodomain proteins regulate gene expression and cell differentiation during early embryonic development, thus mutations in homeobox genes can cause developmental disorders.[5]

Homeosis is a term coined by William Bateson to describe the outright replacement of a discrete body part with another body part, e.g. antennapedia—replacement of the antenna on the head of a fruit fly with legs.[6] The "homeo-" prefix in the words "homeobox" and "homeodomain" stems from this mutational phenotype, which is observed when some of these genes are mutated in animals. The homeobox domain was first identified in a number of Drosophila homeotic and segmentation proteins, but is now known to be well-conserved in many other animals, including vertebrates.[3][7][8]

Discovery edit

 
Drosophila with the antennapedia mutant phenotype exhibit homeotic transformation of the antennae into leg-like structures on the head.

The existence of homeobox genes was first discovered in Drosophila by isolating the gene responsible for a homeotic transformation where legs grow from the head instead of the expected antennae. Walter Gehring identified a gene called antennapedia that caused this homeotic phenotype.[9] Analysis of antennapedia revealed that this gene contained a 180 base pair sequence that encoded a DNA binding domain, which William McGinnis termed the "homeobox".[10] The existence of additional Drosophila genes containing the antennapedia homeobox sequence was independently reported by Ernst Hafen, Michael Levine, William McGinnis, and Walter Jakob Gehring of the University of Basel in Switzerland and Matthew P. Scott and Amy Weiner of Indiana University in Bloomington in 1984.[11][12] Isolation of homologous genes by Edward de Robertis and William McGinnis revealed that numerous genes from a variety of species contained the homeobox.[13][14] Subsequent phylogenetic studies detailing the evolutionary relationship between homeobox-containing genes showed that these genes are present in all bilaterian animals.

Homeodomain structure edit

The characteristic homeodomain protein fold consists of a 60-amino acid long domain composed of three alpha helixes. The following shows the consensus homeodomain (~60 amino acid chain):[15] 

 Helix 1 Helix 2 Helix 3/4 ______________ __________ _________________ RRRKRTAYTRYQLLELEKEFHFNRYLTRRRRIELAHSLNLTERHIKIWFQNRRMKWKKEN ....|....|....|....|....|....|....|....|....|....|....|....| 10 20 30 40 50 60
 
The vnd/NK-2 homeodomain-DNA complex. Helix 3 of the homeodomain binds in the major groove of the DNA and the N-terminal arm binds in the minor groove, in analogy with other homeodomain-DNA complexes.

Helix 2 and helix 3 form a so-called helix-turn-helix (HTH) structure, where the two alpha helices are connected by a short loop region. The N-terminal two helices of the homeodomain are antiparallel and the longer C-terminal helix is roughly perpendicular to the axes established by the first two. It is this third helix that interacts directly with DNA via a number of hydrogen bonds and hydrophobic interactions, as well as indirect interactions via water molecules, which occur between specific side chains and the exposed bases within the major groove of the DNA.[7]

Homeodomain proteins are found in eukaryotes.[2] Through the HTH motif, they share limited sequence similarity and structural similarity to prokaryotic transcription factors,[16] such as lambda phage proteins that alter the expression of genes in prokaryotes. The HTH motif shows some sequence similarity but a similar structure in a wide range of DNA-binding proteins (e.g., cro and repressor proteins, homeodomain proteins, etc.). One of the principal differences between HTH motifs in these different proteins arises from the stereochemical requirement for glycine in the turn which is needed to avoid steric interference of the beta-carbon with the main chain: for cro and repressor proteins the glycine appears to be mandatory, whereas for many of the homeotic and other DNA-binding proteins the requirement is relaxed.

Sequence specificity edit

Homeodomains can bind both specifically and nonspecifically to B-DNA with the C-terminal recognition helix aligning in the DNA's major groove and the unstructured peptide "tail" at the N-terminus aligning in the minor groove. The recognition helix and the inter-helix loops are rich in arginine and lysine residues, which form hydrogen bonds to the DNA backbone. Conserved hydrophobic residues in the center of the recognition helix aid in stabilizing the helix packing. Homeodomain proteins show a preference for the DNA sequence 5'-TAAT-3'; sequence-independent binding occurs with significantly lower affinity. The specificity of a single homeodomain protein is usually not enough to recognize specific target gene promoters, making cofactor binding an important mechanism for controlling binding sequence specificity and target gene expression. To achieve higher target specificity, homeodomain proteins form complexes with other transcription factors to recognize the promoter region of a specific target gene.

Biological function edit

Homeodomain proteins function as transcription factors due to the DNA binding properties of the conserved HTH motif. Homeodomain proteins are considered to be master control genes, meaning that a single protein can regulate expression of many target genes. Homeodomain proteins direct the formation of the body axes and body structures during early embryonic development.[17] Many homeodomain proteins induce cellular differentiation by initiating the cascades of coregulated genes required to produce individual tissues and organs. Other proteins in the family, such as NANOG are involved in maintaining pluripotency and preventing cell differentiation.

Regulation edit

Hox genes and their associated microRNAs are highly conserved developmental master regulators with tight tissue-specific, spatiotemporal control. These genes are known to be dysregulated in several cancers and are often controlled by DNA methylation.[18][19] The regulation of Hox genes is highly complex and involves reciprocal interactions, mostly inhibitory. Drosophila is known to use the polycomb and trithorax complexes to maintain the expression of Hox genes after the down-regulation of the pair-rule and gap genes that occurs during larval development. Polycomb-group proteins can silence the Hox genes by modulation of chromatin structure.[20]

Mutations edit

Mutations to homeobox genes can produce easily visible phenotypic changes in body segment identity, such as the Antennapedia and Bithorax mutant phenotypes in Drosophila. Duplication of homeobox genes can produce new body segments, and such duplications are likely to have been important in the evolution of segmented animals.

Evolution edit

The homeobox itself may have evolved from a non-DNA-binding transmembrane domain at the C-terminus of the MraY enzyme. This is based on metagenomic data acquired from the transitional archaeon, Lokiarchaeum, that is regarded as the prokaryote closest to the ancestor of all eukaryotes.[21][unreliable source?]

Phylogenetic analysis of homeobox gene sequences and homeodomain protein structures suggests that the last common ancestor of plants, fungi, and animals had at least two homeobox genes.[22] Molecular evidence shows that some limited number of Hox genes have existed in the Cnidaria since before the earliest true Bilatera, making these genes pre-Paleozoic.[23] It is accepted that the three major animal ANTP-class clusters, Hox, ParaHox, and NK (MetaHox), are the result of segmental duplications. A first duplication created MetaHox and ProtoHox, the latter of which later duplicated into Hox and ParaHox. The clusters themselves were created by tandem duplications of a single ANTP-class homeobox gene.[24] Gene duplication followed by neofunctionalization is responsible for the many homeobox genes found in eukaryotes.[25][26] Comparison of homeobox genes and gene clusters has been used to understand the evolution of genome structure and body morphology throughout metazoans.[27]

Types of homeobox genes edit

Hox genes edit

 
Hox gene expression in Drosophila melanogaster.
Main article: Hox gene

Hox genes are the most commonly known subset of homeobox genes. They are essential metazoan genes that determine the identity of embryonic regions along the anterior-posterior axis.[28] The first vertebrate Hox gene was isolated in Xenopus by Edward De Robertis and colleagues in 1984.[29] The main interest in this set of genes stems from their unique behavior and arrangement in the genome. Hox genes are typically found in an organized cluster. The linear order of Hox genes within a cluster is directly correlated to the order they are expressed in both time and space during development. This phenomenon is called colinearity.

Mutations in these homeotic genes cause displacement of body segments during embryonic development. This is called ectopia. For example, when one gene is lost the segment develops into a more anterior one, while a mutation that leads to a gain of function causes a segment to develop into a more posterior one. Famous examples are Antennapedia and bithorax in Drosophila, which can cause the development of legs instead of antennae and the development of a duplicated thorax, respectively.[30]

In vertebrates, the four paralog clusters are partially redundant in function, but have also acquired several derived functions. For example, HoxA and HoxD specify segment identity along the limb axis.[31][32] Specific members of the Hox family have been implicated in vascular remodeling, angiogenesis, and disease by orchestrating changes in matrix degradation, integrins, and components of the ECM.[33] HoxA5 is implicated in atherosclerosis.[34][35] HoxD3 and HoxB3 are proinvasive, angiogenic genes that upregulate b3 and a5 integrins and Efna1 in ECs, respectively.[36][37][38][39] HoxA3 induces endothelial cell (EC) migration by upregulating MMP14 and uPAR. Conversely, HoxD10 and HoxA5 have the opposite effect of suppressing EC migration and angiogenesis, and stabilizing adherens junctions by upregulating TIMP1/downregulating uPAR and MMP14, and by upregulating Tsp2/downregulating VEGFR2, Efna1, Hif1alpha and COX-2, respectively.[40][41] HoxA5 also upregulates the tumor suppressor p53 and Akt1 by downregulation of PTEN.[42] Suppression of HoxA5 has been shown to attenuate hemangioma growth.[43] HoxA5 has far-reaching effects on gene expression, causing ~300 genes to become upregulated upon its induction in breast cancer cell lines.[43] HoxA5 protein transduction domain overexpression prevents inflammation shown by inhibition of TNFalpha-inducible monocyte binding to HUVECs.[44][45]

LIM genes edit

Main article: LIM domain

LIM genes (named after the initial letters of the names of three proteins where the characteristic domain was first identified) encode two 60 amino acid cysteine and histidine-rich LIM domains and a homeodomain. The LIM domains function in protein-protein interactions and can bind zinc molecules. LIM domain proteins are found in both the cytosol and the nucleus. They function in cytoskeletal remodeling, at focal adhesion sites, as scaffolds for protein complexes, and as transcription factors.[46]

Pax genes edit

Main article: Pax genes

Most Pax genes contain a homeobox and a paired domain that also binds DNA to increase binding specificity, though some Pax genes have lost all or part of the homeobox sequence.[47] Pax genes function in embryo segmentation, nervous system development, generation of the frontal eye fields, skeletal development, and formation of face structures. Pax 6 is a master regulator of eye development, such that the gene is necessary for development of the optic vesicle and subsequent eye structures.[48]

POU genes edit

Main article: POU family

Proteins containing a POU region consist of a homeodomain and a separate, structurally homologous POU domain that contains two helix-turn-helix motifs and also binds DNA. The two domains are linked by a flexible loop that is long enough to stretch around the DNA helix, allowing the two domains to bind on opposite sides of the target DNA, collectively covering an eight-base segment with consensus sequence 5'-ATGCAAAT-3'. The individual domains of POU proteins bind DNA only weakly, but have strong sequence-specific affinity when linked. The POU domain itself has significant structural similarity with repressors expressed in bacteriophages, particularly lambda phage.

Plant homeobox genes edit

As in animals, the plant homeobox genes code for the typical 60 amino acid long DNA-binding homeodomain or in case of the TALE (three amino acid loop extension) homeobox genes for an atypical homeodomain consisting of 63 amino acids. According to their conserved intron–exon structure and to unique codomain architectures they have been grouped into 14 distinct classes: HD-ZIP I to IV, BEL, KNOX, PLINC, WOX, PHD, DDT, NDX, LD, SAWADEE and PINTOX.[25] Conservation of codomains suggests a common eukaryotic ancestry for TALE[49] and non-TALE homeodomain proteins.[50]

Human homeobox genes edit

The Hox genes in humans are organized in four chromosomal clusters:

ParaHox genes are analogously found in four areas. They include CDX1, CDX2, CDX4; GSX1, GSX2; and PDX1. Other genes considered Hox-like include EVX1, EVX2; GBX1, GBX2; MEOX1, MEOX2; and MNX1. The NK-like (NKL) genes, some of which are considered "MetaHox", are grouped with Hox-like genes into a large ANTP-like group.[51][52]

Humans have a "distal-less homeobox" family: DLX1, DLX2, DLX3, DLX4, DLX5, and DLX6. Dlx genes are involved in the development of the nervous system and of limbs.[53] They are considered a subset of the NK-like genes.[51]

Human TALE (Three Amino acid Loop Extension) homeobox genes for an "atypical" homeodomain consist of 63 rather than 60 amino acids: IRX1, IRX2, IRX3, IRX4, IRX5, IRX6; MEIS1, MEIS2, MEIS3; MKX; PBX1, PBX2, PBX3, PBX4; PKNOX1, PKNOX2; TGIF1, TGIF2, TGIF2LX, TGIF2LY.[51]

In addition, humans have the following homeobox genes and proteins:[51]

  1. ^ Grouped as Lmx 1/5, 2/9, 3/4, and 6/8.
  2. ^ Grouped as Six 1/2, 3/6, and 4/5.
  3. ^ Questionable, per [51]
  4. ^ The Pax genes. Grouped as Pax2/5/8, Pax3/7, and Pax4/6.
  5. ^ Nk4.
  6. ^ Nk5.

See also edit

References edit

  1. ^ PDB: 1AHD​; Billeter M, Qian YQ, Otting G, Müller M, Gehring W, Wüthrich K (December 1993). "Determination of the nuclear magnetic resonance solution structure of an Antennapedia homeodomain-DNA complex". Journal of Molecular Biology. 234 (4): 1084–93. doi:10.1006/jmbi.1993.1661. PMID 7903398.
  2. ^ a b c Bürglin TR, Affolter M (June 2016). "Homeodomain proteins: an update". Chromosoma. 125 (3): 497–521. doi:10.1007/s00412-015-0543-8. PMC 4901127. PMID 26464018.
  3. ^ a b Gehring WJ (August 1992). "The homeobox in perspective". Trends in Biochemical Sciences. 17 (8): 277–80. doi:10.1016/0968-0004(92)90434-B. PMID 1357790.
  4. ^ Gehring WJ (December 1993). "Exploring the homeobox". Gene. 135 (1–2): 215–21. doi:10.1016/0378-1119(93)90068-E. PMID 7903947.
  5. ^ Reference GH. "Homeoboxes". Genetics Home Reference. from the original on 2019-12-21. Retrieved 2019-11-20.
  6. ^ Materials for the study of variation, treated with especial regard to discontinuity in the origin of species William Bateson 1861–1926. London : Macmillan 1894 xv, 598 p
  7. ^ a b Schofield PN (1987). "Patterns, puzzles and paradigms - The riddle of the homeobox". Trends Neurosci. 10: 3–6. doi:10.1016/0166-2236(87)90113-5. S2CID 53188259.
  8. ^ Scott MP, Tamkun JW, Hartzell GW (July 1989). "The structure and function of the homeodomain". Biochimica et Biophysica Acta (BBA) - Reviews on Cancer. 989 (1): 25–48. doi:10.1016/0304-419x(89)90033-4. PMID 2568852.
  9. ^ Garber RL, Kuroiwa A, Gehring WJ (1983). "Genomic and cDNA clones of the homeotic locus Antennapedia in Drosophila". The EMBO Journal. 2 (11): 2027–36. doi:10.1002/j.1460-2075.1983.tb01696.x. PMC 555405. PMID 6416827.
  10. ^ "Walter Jakob Gehring (1939-2014) | The Embryo Project Encyclopedia". embryo.asu.edu. from the original on 2019-12-09. Retrieved 2019-12-09.
  11. ^ McGinnis W, Levine MS, Hafen E, Kuroiwa A, Gehring WJ (1984). "A conserved DNA sequence in homoeotic genes of the Drosophila Antennapedia and bithorax complexes". Nature. 308 (5958): 428–33. Bibcode:1984Natur.308..428M. doi:10.1038/308428a0. PMID 6323992. S2CID 4235713.
  12. ^ Scott MP, Weiner AJ (July 1984). "Structural relationships among genes that control development: sequence homology between the Antennapedia, Ultrabithorax, and fushi tarazu loci of Drosophila". Proceedings of the National Academy of Sciences of the United States of America. 81 (13): 4115–9. Bibcode:1984PNAS...81.4115S. doi:10.1073/pnas.81.13.4115. PMC 345379. PMID 6330741.
  13. ^ Carrasco AE, McGinnis W, Gehring WJ, De Robertis EM (1984). "Cloning of an X. laevis gene expressed during early embryogenesis coding for a peptide region homologous to Drosophila homeotic genes". Cell. 37 (2): 409–414. doi:10.1016/0092-8674(84)90371-4. PMID 6327066. S2CID 30114443.
  14. ^ McGinnis W, Garber RL, Wirz J, Kuroiwa A, Gehring WJ (June 1984). "A homologous protein-coding sequence in Drosophila homeotic genes and its conservation in other metazoans". Cell. 37 (2): 403–8. doi:10.1016/0092-8674(84)90370-2. PMID 6327065. S2CID 40456645. from the original on 2021-05-04. Retrieved 2019-12-09.
  15. ^ Bürglin TR. "The homeobox page" (gif). Karolinksa Institute. from the original on 2011-07-21. Retrieved 2010-01-30.
  16. ^ . www.cathdb.info. Archived from the original on 9 August 2017. Retrieved 27 March 2018.
  17. ^ Corsetti MT, Briata P, Sanseverino L, Daga A, Airoldi I, Simeone A, et al. (September 1992). "Differential DNA binding properties of three human homeodomain proteins". Nucleic Acids Research. 20 (17): 4465–72. doi:10.1093/nar/20.17.4465. PMC 334173. PMID 1357628.
  18. ^ Dunn J, Thabet S, Jo H (July 2015). "Flow-Dependent Epigenetic DNA Methylation in Endothelial Gene Expression and Atherosclerosis". Arteriosclerosis, Thrombosis, and Vascular Biology. 35 (7): 1562–9. doi:10.1161/ATVBAHA.115.305042. PMC 4754957. PMID 25953647.
  19. ^ Bhatlekar S, Fields JZ, Boman BM (August 2014). "HOX genes and their role in the development of human cancers". Journal of Molecular Medicine. 92 (8): 811–23. doi:10.1007/s00109-014-1181-y. PMID 24996520. S2CID 17159381.
  20. ^ Portoso M, Cavalli G (2008). "The Role of RNAi and Noncoding RNAs in Polycomb Mediated Control of Gene Expression and Genomic Programming". RNA and the Regulation of Gene Expression: A Hidden Layer of Complexity. Caister Academic Press. ISBN 978-1-904455-25-7. from the original on 2012-01-02. Retrieved 2008-02-27.
  21. ^ Bozorgmehr JH (2018). "The origin of the Homeobox at the C-terminus of MraY in Lokiarchaea". doi:10.13140/RG.2.2.35941.65760. from the original on 2021-05-04. Retrieved 2018-10-26 – via ResearchGate. {{cite journal}}: Cite journal requires |journal= (help)
  22. ^ Bharathan G, Janssen BJ, Kellogg EA, Sinha N (December 1997). "Did homeodomain proteins duplicate before the origin of angiosperms, fungi, and metazoa?". Proceedings of the National Academy of Sciences of the United States of America. 94 (25): 13749–53. Bibcode:1997PNAS...9413749B. doi:10.1073/pnas.94.25.13749. JSTOR 43805. PMC 28378. PMID 9391098.
  23. ^ Ryan JF, Mazza ME, Pang K, Matus DQ, Baxevanis AD, Martindale MQ, et al. (January 2007). "Pre-bilaterian origins of the Hox cluster and the Hox code: evidence from the sea anemone, Nematostella vectensis". PLOS ONE. 2 (1): e153. Bibcode:2007PLoSO...2..153R. doi:10.1371/journal.pone.0000153. PMC 1779807. PMID 17252055.
  24. ^ Garcia-Fernàndez J (December 2005). "The genesis and evolution of homeobox gene clusters". Nature Reviews Genetics. 6 (12): 881–92. doi:10.1038/nrg1723. PMID 16341069. S2CID 42823485.
  25. ^ a b Mukherjee K, Brocchieri L, Bürglin TR (December 2009). "A comprehensive classification and evolutionary analysis of plant homeobox genes". Molecular Biology and Evolution. 26 (12): 2775–94. doi:10.1093/molbev/msp201. PMC 2775110. PMID 19734295.
  26. ^ Holland PW (2013). "Evolution of homeobox genes". Wiley Interdisciplinary Reviews: Developmental Biology. 2 (1): 31–45. doi:10.1002/wdev.78. PMID 23799629. S2CID 44396110.
  27. ^ Ferrier DE (2016). "Evolution of Homeobox Gene Clusters in Animals: The Giga-Cluster and Primary vs. Secondary Clustering". Frontiers in Ecology and Evolution. 4. doi:10.3389/fevo.2016.00036. hdl:10023/8685. ISSN 2296-701X.
  28. ^ Alonso CR (November 2002). "Hox proteins: sculpting body parts by activating localized cell death". Current Biology. 12 (22): R776-8. Bibcode:2002CBio...12.R776A. doi:10.1016/S0960-9822(02)01291-5. PMID 12445403. S2CID 17558233.
  29. ^ Carrasco AE, McGinnis W, Gehring WJ, De Robertis EM (June 1984). "Cloning of an X. laevis gene expressed during early embryogenesis coding for a peptide region homologous to Drosophila homeotic genes". Cell. 37 (2): 409–14. doi:10.1016/0092-8674(84)90371-4. PMID 6327066. S2CID 30114443.
  30. ^ Schneuwly S, Klemenz R, Gehring WJ (1987). "Redesigning the body plan of Drosophila by ectopic expression of the homoeotic gene Antennapedia". Nature. 325 (6107): 816–8. Bibcode:1987Natur.325..816S. doi:10.1038/325816a0. PMID 3821869. S2CID 4320668.
  31. ^ Fromental-Ramain C, Warot X, Messadecq N, LeMeur M, Dollé P, Chambon P (October 1996). "Hoxa-13 and Hoxd-13 play a crucial role in the patterning of the limb autopod". Development. 122 (10): 2997–3011. doi:10.1242/dev.122.10.2997. PMID 8898214.
  32. ^ Zákány J, Duboule D (April 1999). "Hox genes in digit development and evolution". Cell and Tissue Research. 296 (1): 19–25. doi:10.1007/s004410051262. PMID 10199961. S2CID 3192774.
  33. ^ Gorski DH, Walsh K (November 2000). "The role of homeobox genes in vascular remodeling and angiogenesis". Circulation Research. 87 (10): 865–72. doi:10.1161/01.res.87.10.865. PMID 11073881.
  34. ^ Dunn J, Thabet S, Jo H (July 2015). "Flow-Dependent Epigenetic DNA Methylation in Endothelial Gene Expression and Atherosclerosis". Arteriosclerosis, Thrombosis, and Vascular Biology. 35 (7): 1562–9. doi:10.1161/ATVBAHA.115.305042. PMC 4754957. PMID 25953647.
  35. ^ Dunn J, Simmons R, Thabet S, Jo H (October 2015). "The role of epigenetics in the endothelial cell shear stress response and atherosclerosis". The International Journal of Biochemistry & Cell Biology. 67: 167–76. doi:10.1016/j.biocel.2015.05.001. PMC 4592147. PMID 25979369.
  36. ^ Boudreau N, Andrews C, Srebrow A, Ravanpay A, Cheresh DA (October 1997). "Induction of the angiogenic phenotype by Hox D3". The Journal of Cell Biology. 139 (1): 257–64. doi:10.1083/jcb.139.1.257. PMC 2139816. PMID 9314544.
  37. ^ Boudreau NJ, Varner JA (February 2004). "The homeobox transcription factor Hox D3 promotes integrin alpha5beta1 expression and function during angiogenesis". The Journal of Biological Chemistry. 279 (6): 4862–8. doi:10.1074/jbc.M305190200. PMID 14610084.
  38. ^ Myers C, Charboneau A, Boudreau N (January 2000). "Homeobox B3 promotes capillary morphogenesis and angiogenesis". The Journal of Cell Biology. 148 (2): 343–51. doi:10.1083/jcb.148.2.343. PMC 2174277. PMID 10648567.
  39. ^ Chen Y, Xu B, Arderiu G, Hashimoto T, Young WL, Boudreau N, et al. (November 2004). "Retroviral delivery of homeobox D3 gene induces cerebral angiogenesis in mice". Journal of Cerebral Blood Flow and Metabolism. 24 (11): 1280–7. doi:10.1097/01.WCB.0000141770.09022.AB. PMID 15545924.
  40. ^ Myers C, Charboneau A, Cheung I, Hanks D, Boudreau N (December 2002). "Sustained expression of homeobox D10 inhibits angiogenesis". The American Journal of Pathology. 161 (6): 2099–109. doi:10.1016/S0002-9440(10)64488-4. PMC 1850921. PMID 12466126.
  41. ^ Mace KA, Hansen SL, Myers C, Young DM, Boudreau N (June 2005). "HOXA3 induces cell migration in endothelial and epithelial cells promoting angiogenesis and wound repair". Journal of Cell Science. 118 (Pt 12): 2567–77. doi:10.1242/jcs.02399. PMID 15914537.
  42. ^ Rhoads K, Arderiu G, Charboneau A, Hansen SL, Hoffman W, Boudreau N (2005). "A role for Hox A5 in regulating angiogenesis and vascular patterning". Lymphatic Research and Biology. 3 (4): 240–52. doi:10.1089/lrb.2005.3.240. PMID 16379594.
  43. ^ a b Arderiu G, Cuevas I, Chen A, Carrio M, East L, Boudreau NJ (2007). "HoxA5 stabilizes adherens junctions via increased Akt1". Cell Adhesion & Migration. 1 (4): 185–95. doi:10.4161/cam.1.4.5448. PMC 2634105. PMID 19262140.
  44. ^ Zhu Y, Cuevas IC, Gabriel RA, Su H, Nishimura S, Gao P, et al. (June 2009). "Restoring transcription factor HoxA5 expression inhibits the growth of experimental hemangiomas in the brain". Journal of Neuropathology and Experimental Neurology. 68 (6): 626–32. doi:10.1097/NEN.0b013e3181a491ce. PMC 2728585. PMID 19458547.
  45. ^ Chen H, Rubin E, Zhang H, Chung S, Jie CC, Garrett E, et al. (May 2005). "Identification of transcriptional targets of HOXA5". The Journal of Biological Chemistry. 280 (19): 19373–80. doi:10.1074/jbc.M413528200. PMID 15757903.
  46. ^ Kadrmas JL, Beckerle MC (November 2004). "The LIM domain: from the cytoskeleton to the nucleus". Nature Reviews Molecular Cell Biology. 5 (11): 920–31. doi:10.1038/nrm1499. PMID 15520811. S2CID 6030950.
  47. ^ Gruss P, Walther C (May 1992). "Pax in development". Cell. 69 (5): 719–22. doi:10.1016/0092-8674(92)90281-G. PMID 1591773. S2CID 44613005. from the original on 2021-05-02. Retrieved 2019-12-11.
  48. ^ Walther C, Gruss P (December 1991). "Pax-6, a murine paired box gene, is expressed in the developing CNS". Development. 113 (4): 1435–49. doi:10.1242/dev.113.4.1435. PMID 1687460.
  49. ^ Bürglin TR (November 1997). "Analysis of TALE superclass homeobox genes (MEIS, PBC, KNOX, Iroquois, TGIF) reveals a novel domain conserved between plants and animals". Nucleic Acids Research. 25 (21): 4173–80. doi:10.1093/nar/25.21.4173. PMC 147054. PMID 9336443.
  50. ^ Derelle R, Lopez P, Le Guyader H, Manuel M (2007). "Homeodomain proteins belong to the ancestral molecular toolkit of eukaryotes". Evolution & Development. 9 (3): 212–9. doi:10.1111/j.1525-142X.2007.00153.x. PMID 17501745. S2CID 9530210.
  51. ^ a b c d e Holland PW, Booth HA, Bruford EA (October 2007). "Classification and nomenclature of all human homeobox genes". BMC Biology. 5 (1): 47. doi:10.1186/1741-7007-5-47. PMC 2211742. PMID 17963489.
  52. ^ Coulier F, Popovici C, Villet R, Birnbaum D (15 December 2000). "MetaHox gene clusters". Journal of Experimental Zoology. 288 (4): 345–351. doi:10.1002/1097-010X(20001215)288:4<345::AID-JEZ7>3.0.CO;2-Y. PMID 11144283.
  53. ^ Kraus P, Lufkin T (July 2006). "Dlx homeobox gene control of mammalian limb and craniofacial development". American Journal of Medical Genetics. Part A. 140 (13): 1366–74. doi:10.1002/ajmg.a.31252. PMID 16688724. S2CID 32619323.

Further reading edit

  • Lodish H, Berk A, Matsudaira P, Kaiser CA, Krieger M, Scott MP, et al. (2003). Molecular Cell Biology (5th ed.). New York: W.H. Freeman and Company. ISBN 978-0-7167-4366-8.
  • Tooze C, Branden J (1999). Introduction to protein structure (2nd ed.). New York: Garland Pub. pp. 159–66. ISBN 978-0-8153-2305-1.
  • Ogishima S, Tanaka H (January 2007). "Missing link in the evolution of Hox clusters". Gene. 387 (1–2): 21–30. doi:10.1016/j.gene.2006.08.011. PMID 17098381.

External links edit

  • The Homeodomain Resource (National Human Genome Research Institute, National Institutes of Health)
  • HomeoDB: a database of homeobox genes diversity. Zhong YF, Butts T, Holland PWH, since 2008. 2021-06-01 at the Wayback Machine
  • Eukaryotic Linear Motif resource motif class LIG_HOMEOBOX
  • Homeobox at the U.S. National Library of Medicine Medical Subject Headings (MeSH)
This article incorporates text from the public domain Pfam and InterPro: IPR001356

April 26, 2024
homeobox, homeobox, sequence, around, base, pairs, long, that, regulates, large, scale, anatomical, features, early, stages, embryonic, development, mutations, homeobox, change, large, scale, anatomical, features, full, grown, organism, homeodomainthe, antenna. A homeobox is a DNA sequence around 180 base pairs long that regulates large scale anatomical features in the early stages of embryonic development Mutations in a homeobox may change large scale anatomical features of the full grown organism HomeodomainThe Antennapedia homeodomain protein from Drosophila melanogaster bound to a fragment of DNA 1 The recognition helix and unstructured N terminus are bound in the major and minor grooves respectively IdentifiersSymbolHomeodomainPfamPF00046Pfam clanCL0123InterProIPR001356SMARTSM00389PROSITEPDOC00027SCOP21ahd SCOPe SUPFAMAvailable protein structures Pfam structures ECOD PDBRCSB PDB PDBe PDBjPDBsumstructure summaryPDB1ahd 1akh 1apl 1au7 1b72 1b8i 1bw5 1cqt 1du0 1du6 1e3o 1enh 1f43 1fjl 1ftt 1ftz 1gt0 1hdd 1hdp 1hf0 1hom 1ic8 1ig7 1jgg 1k61 1kz2 1le8 1lfb 1lfu 1mh3 1mh4 1mnm 1nk2 1nk3 1o4x 1ocp 1oct 1p7i 1p7j 1pog 1puf 1qry 1s7e 1san 1uhs 1vnd 1wi3 1x2m 1x2n 1yrn 1yz8 1zq3 1ztr 2cqx 2cra 2cue 2cuf 2dmq 2e1o 2ecb 2ecc 2h8r 2hdd 2hi3 2hoa 2jwt 2lfb 2p81 2r5y 2r5z 3hdd 9ant Homeoboxes are found within genes that are involved in the regulation of patterns of anatomical development morphogenesis in animals fungi plants and numerous single cell eukaryotes 2 Homeobox genes encode homeodomain protein products that are transcription factors sharing a characteristic protein fold structure that binds DNA to regulate expression of target genes 3 4 2 Homeodomain proteins regulate gene expression and cell differentiation during early embryonic development thus mutations in homeobox genes can cause developmental disorders 5 Homeosis is a term coined by William Bateson to describe the outright replacement of a discrete body part with another body part e g antennapedia replacement of the antenna on the head of a fruit fly with legs 6 The homeo prefix in the words homeobox and homeodomain stems from this mutational phenotype which is observed when some of these genes are mutated in animals The homeobox domain was first identified in a number of Drosophila homeotic and segmentation proteins but is now known to be well conserved in many other animals including vertebrates 3 7 8 Contents 1 Discovery 2 Homeodomain structure 2 1 Sequence specificity 3 Biological function 4 Regulation 5 Mutations 6 Evolution 7 Types of homeobox genes 7 1 Hox genes 7 2 LIM genes 7 3 Pax genes 7 4 POU genes 8 Plant homeobox genes 9 Human homeobox genes 10 See also 11 References 12 Further reading 13 External linksDiscovery edit nbsp Drosophila with the antennapedia mutant phenotype exhibit homeotic transformation of the antennae into leg like structures on the head The existence of homeobox genes was first discovered in Drosophila by isolating the gene responsible for a homeotic transformation where legs grow from the head instead of the expected antennae Walter Gehring identified a gene called antennapedia that caused this homeotic phenotype 9 Analysis of antennapedia revealed that this gene contained a 180 base pair sequence that encoded a DNA binding domain which William McGinnis termed the homeobox 10 The existence of additional Drosophila genes containing the antennapedia homeobox sequence was independently reported by Ernst Hafen Michael Levine William McGinnis and Walter Jakob Gehring of the University of Basel in Switzerland and Matthew P Scott and Amy Weiner of Indiana University in Bloomington in 1984 11 12 Isolation of homologous genes by Edward de Robertis and William McGinnis revealed that numerous genes from a variety of species contained the homeobox 13 14 Subsequent phylogenetic studies detailing the evolutionary relationship between homeobox containing genes showed that these genes are present in all bilaterian animals Homeodomain structure editThe characteristic homeodomain protein fold consists of a 60 amino acid long domain composed of three alpha helixes The following shows the consensus homeodomain 60 amino acid chain 15 Helix 1 Helix 2 Helix 3 4 RRRKRTAYTRYQLLELEKEFHFNRYLTRRRRIELAHSLNLTERHIKIWFQNRRMKWKKEN 10 20 30 40 50 60 nbsp The vnd NK 2 homeodomain DNA complex Helix 3 of the homeodomain binds in the major groove of the DNA and the N terminal arm binds in the minor groove in analogy with other homeodomain DNA complexes Helix 2 and helix 3 form a so called helix turn helix HTH structure where the two alpha helices are connected by a short loop region The N terminal two helices of the homeodomain are antiparallel and the longer C terminal helix is roughly perpendicular to the axes established by the first two It is this third helix that interacts directly with DNA via a number of hydrogen bonds and hydrophobic interactions as well as indirect interactions via water molecules which occur between specific side chains and the exposed bases within the major groove of the DNA 7 Homeodomain proteins are found in eukaryotes 2 Through the HTH motif they share limited sequence similarity and structural similarity to prokaryotic transcription factors 16 such as lambda phage proteins that alter the expression of genes in prokaryotes The HTH motif shows some sequence similarity but a similar structure in a wide range of DNA binding proteins e g cro and repressor proteins homeodomain proteins etc One of the principal differences between HTH motifs in these different proteins arises from the stereochemical requirement for glycine in the turn which is needed to avoid steric interference of the beta carbon with the main chain for cro and repressor proteins the glycine appears to be mandatory whereas for many of the homeotic and other DNA binding proteins the requirement is relaxed Sequence specificity edit Homeodomains can bind both specifically and nonspecifically to B DNA with the C terminal recognition helix aligning in the DNA s major groove and the unstructured peptide tail at the N terminus aligning in the minor groove The recognition helix and the inter helix loops are rich in arginine and lysine residues which form hydrogen bonds to the DNA backbone Conserved hydrophobic residues in the center of the recognition helix aid in stabilizing the helix packing Homeodomain proteins show a preference for the DNA sequence 5 TAAT 3 sequence independent binding occurs with significantly lower affinity The specificity of a single homeodomain protein is usually not enough to recognize specific target gene promoters making cofactor binding an important mechanism for controlling binding sequence specificity and target gene expression To achieve higher target specificity homeodomain proteins form complexes with other transcription factors to recognize the promoter region of a specific target gene Biological function editHomeodomain proteins function as transcription factors due to the DNA binding properties of the conserved HTH motif Homeodomain proteins are considered to be master control genes meaning that a single protein can regulate expression of many target genes Homeodomain proteins direct the formation of the body axes and body structures during early embryonic development 17 Many homeodomain proteins induce cellular differentiation by initiating the cascades of coregulated genes required to produce individual tissues and organs Other proteins in the family such as NANOG are involved in maintaining pluripotency and preventing cell differentiation Regulation editHox genes and their associated microRNAs are highly conserved developmental master regulators with tight tissue specific spatiotemporal control These genes are known to be dysregulated in several cancers and are often controlled by DNA methylation 18 19 The regulation of Hox genes is highly complex and involves reciprocal interactions mostly inhibitory Drosophila is known to use the polycomb and trithorax complexes to maintain the expression of Hox genes after the down regulation of the pair rule and gap genes that occurs during larval development Polycomb group proteins can silence the Hox genes by modulation of chromatin structure 20 Mutations editMutations to homeobox genes can produce easily visible phenotypic changes in body segment identity such as the Antennapedia and Bithorax mutant phenotypes in Drosophila Duplication of homeobox genes can produce new body segments and such duplications are likely to have been important in the evolution of segmented animals Evolution editThe homeobox itself may have evolved from a non DNA binding transmembrane domain at the C terminus of the MraY enzyme This is based on metagenomic data acquired from the transitional archaeon Lokiarchaeum that is regarded as the prokaryote closest to the ancestor of all eukaryotes 21 unreliable source Phylogenetic analysis of homeobox gene sequences and homeodomain protein structures suggests that the last common ancestor of plants fungi and animals had at least two homeobox genes 22 Molecular evidence shows that some limited number of Hox genes have existed in the Cnidaria since before the earliest true Bilatera making these genes pre Paleozoic 23 It is accepted that the three major animal ANTP class clusters Hox ParaHox and NK MetaHox are the result of segmental duplications A first duplication created MetaHox and ProtoHox the latter of which later duplicated into Hox and ParaHox The clusters themselves were created by tandem duplications of a single ANTP class homeobox gene 24 Gene duplication followed by neofunctionalization is responsible for the many homeobox genes found in eukaryotes 25 26 Comparison of homeobox genes and gene clusters has been used to understand the evolution of genome structure and body morphology throughout metazoans 27 Types of homeobox genes editHox genes edit nbsp Hox gene expression in Drosophila melanogaster Main article Hox gene Hox genes are the most commonly known subset of homeobox genes They are essential metazoan genes that determine the identity of embryonic regions along the anterior posterior axis 28 The first vertebrate Hox gene was isolated in Xenopus by Edward De Robertis and colleagues in 1984 29 The main interest in this set of genes stems from their unique behavior and arrangement in the genome Hox genes are typically found in an organized cluster The linear order of Hox genes within a cluster is directly correlated to the order they are expressed in both time and space during development This phenomenon is called colinearity Mutations in these homeotic genes cause displacement of body segments during embryonic development This is called ectopia For example when one gene is lost the segment develops into a more anterior one while a mutation that leads to a gain of function causes a segment to develop into a more posterior one Famous examples are Antennapedia and bithorax in Drosophila which can cause the development of legs instead of antennae and the development of a duplicated thorax respectively 30 In vertebrates the four paralog clusters are partially redundant in function but have also acquired several derived functions For example HoxA and HoxD specify segment identity along the limb axis 31 32 Specific members of the Hox family have been implicated in vascular remodeling angiogenesis and disease by orchestrating changes in matrix degradation integrins and components of the ECM 33 HoxA5 is implicated in atherosclerosis 34 35 HoxD3 and HoxB3 are proinvasive angiogenic genes that upregulate b3 and a5 integrins and Efna1 in ECs respectively 36 37 38 39 HoxA3 induces endothelial cell EC migration by upregulating MMP14 and uPAR Conversely HoxD10 and HoxA5 have the opposite effect of suppressing EC migration and angiogenesis and stabilizing adherens junctions by upregulating TIMP1 downregulating uPAR and MMP14 and by upregulating Tsp2 downregulating VEGFR2 Efna1 Hif1alpha and COX 2 respectively 40 41 HoxA5 also upregulates the tumor suppressor p53 and Akt1 by downregulation of PTEN 42 Suppression of HoxA5 has been shown to attenuate hemangioma growth 43 HoxA5 has far reaching effects on gene expression causing 300 genes to become upregulated upon its induction in breast cancer cell lines 43 HoxA5 protein transduction domain overexpression prevents inflammation shown by inhibition of TNFalpha inducible monocyte binding to HUVECs 44 45 LIM genes edit Main article LIM domain LIM genes named after the initial letters of the names of three proteins where the characteristic domain was first identified encode two 60 amino acid cysteine and histidine rich LIM domains and a homeodomain The LIM domains function in protein protein interactions and can bind zinc molecules LIM domain proteins are found in both the cytosol and the nucleus They function in cytoskeletal remodeling at focal adhesion sites as scaffolds for protein complexes and as transcription factors 46 Pax genes edit Main article Pax genes Most Pax genes contain a homeobox and a paired domain that also binds DNA to increase binding specificity though some Pax genes have lost all or part of the homeobox sequence 47 Pax genes function in embryo segmentation nervous system development generation of the frontal eye fields skeletal development and formation of face structures Pax 6 is a master regulator of eye development such that the gene is necessary for development of the optic vesicle and subsequent eye structures 48 POU genes edit Main article POU family Proteins containing a POU region consist of a homeodomain and a separate structurally homologous POU domain that contains two helix turn helix motifs and also binds DNA The two domains are linked by a flexible loop that is long enough to stretch around the DNA helix allowing the two domains to bind on opposite sides of the target DNA collectively covering an eight base segment with consensus sequence 5 ATGCAAAT 3 The individual domains of POU proteins bind DNA only weakly but have strong sequence specific affinity when linked The POU domain itself has significant structural similarity with repressors expressed in bacteriophages particularly lambda phage Plant homeobox genes editAs in animals the plant homeobox genes code for the typical 60 amino acid long DNA binding homeodomain or in case of the TALE three amino acid loop extension homeobox genes for an atypical homeodomain consisting of 63 amino acids According to their conserved intron exon structure and to unique codomain architectures they have been grouped into 14 distinct classes HD ZIP I to IV BEL KNOX PLINC WOX PHD DDT NDX LD SAWADEE and PINTOX 25 Conservation of codomains suggests a common eukaryotic ancestry for TALE 49 and non TALE homeodomain proteins 50 Human homeobox genes editThe Hox genes in humans are organized in four chromosomal clusters name chromosome gene HOXA or sometimes HOX1 HOXA chromosome 7 HOXA1 HOXA2 HOXA3 HOXA4 HOXA5 HOXA6 HOXA7 HOXA9 HOXA10 HOXA11 HOXA13 HOXB HOXB chromosome 17 HOXB1 HOXB2 HOXB3 HOXB4 HOXB5 HOXB6 HOXB7 HOXB8 HOXB9 HOXB13 HOXC HOXC chromosome 12 HOXC4 HOXC5 HOXC6 HOXC8 HOXC9 HOXC10 HOXC11 HOXC12 HOXC13 HOXD HOXD chromosome 2 HOXD1 HOXD3 HOXD4 HOXD8 HOXD9 HOXD10 HOXD11 HOXD12 HOXD13 ParaHox genes are analogously found in four areas They include CDX1 CDX2 CDX4 GSX1 GSX2 and PDX1 Other genes considered Hox like include EVX1 EVX2 GBX1 GBX2 MEOX1 MEOX2 and MNX1 The NK like NKL genes some of which are considered MetaHox are grouped with Hox like genes into a large ANTP like group 51 52 Humans have a distal less homeobox family DLX1 DLX2 DLX3 DLX4 DLX5 and DLX6 Dlx genes are involved in the development of the nervous system and of limbs 53 They are considered a subset of the NK like genes 51 Human TALE Three Amino acid Loop Extension homeobox genes for an atypical homeodomain consist of 63 rather than 60 amino acids IRX1 IRX2 IRX3 IRX4 IRX5 IRX6 MEIS1 MEIS2 MEIS3 MKX PBX1 PBX2 PBX3 PBX4 PKNOX1 PKNOX2 TGIF1 TGIF2 TGIF2LX TGIF2LY 51 In addition humans have the following homeobox genes and proteins 51 LIM class ISL1 ISL2 LHX1 LHX2 LHX3 LHX4 LHX5 LHX6 LHX8 LHX9 a LMX1A LMX1B POU class HDX POU1F1 POU2F1 POU2F2 POU2F3 POU3F1 POU3F2 POU3F3 POU3F4 POU4F1 POU4F2 POU4F3 POU5F1 POU5F1P1 POU5F1P4 POU5F2 POU6F1 and POU6F2 CERS class LASS2 LASS3 LASS4 LASS5 LASS6 HNF class HMBOX1 HNF1A HNF1B SINE class SIX1 SIX2 SIX3 SIX4 SIX5 SIX6 b CUT class ONECUT1 ONECUT2 ONECUT3 CUX1 CUX2 SATB1 SATB2 ZF class ADNP ADNP2 TSHZ1 TSHZ2 TSHZ3 ZEB1 ZEB2 ZFHX2 ZFHX3 ZFHX4 ZHX1 HOMEZ PRD class ALX1 CART1 ALX3 ALX4 ARGFX ARX DMBX1 DPRX DRGX DUXA DUXB DUX 1 2 3 4 4c 5 c ESX1 GSC GSC2 HESX1 HOPX ISX LEUTX MIXL1 NOBOX OTP OTX1 OTX2 CRX PAX2 PAX3 PAX4 PAX5 PAX6 PAX7 PAX8 d PHOX2A PHOX2B PITX1 PITX2 PITX3 PROP1 PRRX1 PRRX2 RAX RAX2 RHOXF1 RHOXF2 2B SEBOX SHOX SHOX2 TPRX1 UNCX VSX1 VSX2 NKL class BARHL1 BARHL2 BARX1 BARX2 BSX DBX1 DBX2 EMX1 EMX2 EN1 EN2 HHEX HLX1 LBX1 LBX2 MSX1 MSX2 NANOG NOTO TLX1 TLX2 TLX3 TSHZ1 TSHZ2 TSHZ3 VAX1 VAX2 VENTX Nkx NKX2 1 NKX2 4 NKX2 2 NKX2 8 NKX3 1 NKX3 2 NKX2 3 NKX2 5 NKX2 6 e HMX1 HMX2 HMX3 f NKX6 1 NKX6 2 NKX6 3 Grouped as Lmx 1 5 2 9 3 4 and 6 8 Grouped as Six 1 2 3 6 and 4 5 Questionable per 51 The Pax genes Grouped as Pax2 5 8 Pax3 7 and Pax4 6 Nk4 Nk5 See also editEvolutionary developmental biology Body planReferences edit PDB 1AHD Billeter M Qian YQ Otting G Muller M Gehring W Wuthrich K December 1993 Determination of the nuclear magnetic resonance solution structure of an Antennapedia homeodomain DNA complex Journal of Molecular Biology 234 4 1084 93 doi 10 1006 jmbi 1993 1661 PMID 7903398 a b c Burglin TR Affolter M June 2016 Homeodomain proteins an update Chromosoma 125 3 497 521 doi 10 1007 s00412 015 0543 8 PMC 4901127 PMID 26464018 a b Gehring WJ August 1992 The homeobox in perspective Trends in Biochemical Sciences 17 8 277 80 doi 10 1016 0968 0004 92 90434 B PMID 1357790 Gehring WJ December 1993 Exploring the homeobox Gene 135 1 2 215 21 doi 10 1016 0378 1119 93 90068 E PMID 7903947 Reference GH Homeoboxes Genetics Home Reference Archived from the original on 2019 12 21 Retrieved 2019 11 20 Materials for the study of variation treated with especial regard to discontinuity in the origin of species William Bateson 1861 1926 London Macmillan 1894 xv 598 p a b Schofield PN 1987 Patterns puzzles and paradigms The riddle of the homeobox Trends Neurosci 10 3 6 doi 10 1016 0166 2236 87 90113 5 S2CID 53188259 Scott MP Tamkun JW Hartzell GW July 1989 The structure and function of the homeodomain Biochimica et Biophysica Acta BBA Reviews on Cancer 989 1 25 48 doi 10 1016 0304 419x 89 90033 4 PMID 2568852 Garber RL Kuroiwa A Gehring WJ 1983 Genomic and cDNA clones of the homeotic locus Antennapedia in Drosophila The EMBO Journal 2 11 2027 36 doi 10 1002 j 1460 2075 1983 tb01696 x PMC 555405 PMID 6416827 Walter Jakob Gehring 1939 2014 The Embryo Project Encyclopedia embryo asu edu Archived from the original on 2019 12 09 Retrieved 2019 12 09 McGinnis W Levine MS Hafen E Kuroiwa A Gehring WJ 1984 A conserved DNA sequence in homoeotic genes of the Drosophila Antennapedia and bithorax complexes Nature 308 5958 428 33 Bibcode 1984Natur 308 428M doi 10 1038 308428a0 PMID 6323992 S2CID 4235713 Scott MP Weiner AJ July 1984 Structural relationships among genes that control development sequence homology between the Antennapedia Ultrabithorax and fushi tarazu loci of Drosophila Proceedings of the National Academy of Sciences of the United States of America 81 13 4115 9 Bibcode 1984PNAS 81 4115S doi 10 1073 pnas 81 13 4115 PMC 345379 PMID 6330741 Carrasco AE McGinnis W Gehring WJ De Robertis EM 1984 Cloning of an X laevis gene expressed during early embryogenesis coding for a peptide region homologous to Drosophila homeotic genes Cell 37 2 409 414 doi 10 1016 0092 8674 84 90371 4 PMID 6327066 S2CID 30114443 McGinnis W Garber RL Wirz J Kuroiwa A Gehring WJ June 1984 A homologous protein coding sequence in Drosophila homeotic genes and its conservation in other metazoans Cell 37 2 403 8 doi 10 1016 0092 8674 84 90370 2 PMID 6327065 S2CID 40456645 Archived from the original on 2021 05 04 Retrieved 2019 12 09 Burglin TR The homeobox page gif Karolinksa Institute Archived from the original on 2011 07 21 Retrieved 2010 01 30 CATH Superfamily 1 10 10 60 www cathdb info Archived from the original on 9 August 2017 Retrieved 27 March 2018 Corsetti MT Briata P Sanseverino L Daga A Airoldi I Simeone A et al September 1992 Differential DNA binding properties of three human homeodomain proteins Nucleic Acids Research 20 17 4465 72 doi 10 1093 nar 20 17 4465 PMC 334173 PMID 1357628 Dunn J Thabet S Jo H July 2015 Flow Dependent Epigenetic DNA Methylation in Endothelial Gene Expression and Atherosclerosis Arteriosclerosis Thrombosis and Vascular Biology 35 7 1562 9 doi 10 1161 ATVBAHA 115 305042 PMC 4754957 PMID 25953647 Bhatlekar S Fields JZ Boman BM August 2014 HOX genes and their role in the development of human cancers Journal of Molecular Medicine 92 8 811 23 doi 10 1007 s00109 014 1181 y PMID 24996520 S2CID 17159381 Portoso M Cavalli G 2008 The Role of RNAi and Noncoding RNAs in Polycomb Mediated Control of Gene Expression and Genomic Programming RNA and the Regulation of Gene Expression A Hidden Layer of Complexity Caister Academic Press ISBN 978 1 904455 25 7 Archived from the original on 2012 01 02 Retrieved 2008 02 27 Bozorgmehr JH 2018 The origin of the Homeobox at the C terminus of MraY in Lokiarchaea doi 10 13140 RG 2 2 35941 65760 Archived from the original on 2021 05 04 Retrieved 2018 10 26 via ResearchGate a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help Bharathan G Janssen BJ Kellogg EA Sinha N December 1997 Did homeodomain proteins duplicate before the origin of angiosperms fungi and metazoa Proceedings of the National Academy of Sciences of the United States of America 94 25 13749 53 Bibcode 1997PNAS 9413749B doi 10 1073 pnas 94 25 13749 JSTOR 43805 PMC 28378 PMID 9391098 Ryan JF Mazza ME Pang K Matus DQ Baxevanis AD Martindale MQ et al January 2007 Pre bilaterian origins of the Hox cluster and the Hox code evidence from the sea anemone Nematostella vectensis PLOS ONE 2 1 e153 Bibcode 2007PLoSO 2 153R doi 10 1371 journal pone 0000153 PMC 1779807 PMID 17252055 Garcia Fernandez J December 2005 The genesis and evolution of homeobox gene clusters Nature Reviews Genetics 6 12 881 92 doi 10 1038 nrg1723 PMID 16341069 S2CID 42823485 a b Mukherjee K Brocchieri L Burglin TR December 2009 A comprehensive classification and evolutionary analysis of plant homeobox genes Molecular Biology and Evolution 26 12 2775 94 doi 10 1093 molbev msp201 PMC 2775110 PMID 19734295 Holland PW 2013 Evolution of homeobox genes Wiley Interdisciplinary Reviews Developmental Biology 2 1 31 45 doi 10 1002 wdev 78 PMID 23799629 S2CID 44396110 Ferrier DE 2016 Evolution of Homeobox Gene Clusters in Animals The Giga Cluster and Primary vs Secondary Clustering Frontiers in Ecology and Evolution 4 doi 10 3389 fevo 2016 00036 hdl 10023 8685 ISSN 2296 701X Alonso CR November 2002 Hox proteins sculpting body parts by activating localized cell death Current Biology 12 22 R776 8 Bibcode 2002CBio 12 R776A doi 10 1016 S0960 9822 02 01291 5 PMID 12445403 S2CID 17558233 Carrasco AE McGinnis W Gehring WJ De Robertis EM June 1984 Cloning of an X laevis gene expressed during early embryogenesis coding for a peptide region homologous to Drosophila homeotic genes Cell 37 2 409 14 doi 10 1016 0092 8674 84 90371 4 PMID 6327066 S2CID 30114443 Schneuwly S Klemenz R Gehring WJ 1987 Redesigning the body plan of Drosophila by ectopic expression of the homoeotic gene Antennapedia Nature 325 6107 816 8 Bibcode 1987Natur 325 816S doi 10 1038 325816a0 PMID 3821869 S2CID 4320668 Fromental Ramain C Warot X Messadecq N LeMeur M Dolle P Chambon P October 1996 Hoxa 13 and Hoxd 13 play a crucial role in the patterning of the limb autopod Development 122 10 2997 3011 doi 10 1242 dev 122 10 2997 PMID 8898214 Zakany J Duboule D April 1999 Hox genes in digit development and evolution Cell and Tissue Research 296 1 19 25 doi 10 1007 s004410051262 PMID 10199961 S2CID 3192774 Gorski DH Walsh K November 2000 The role of homeobox genes in vascular remodeling and angiogenesis Circulation Research 87 10 865 72 doi 10 1161 01 res 87 10 865 PMID 11073881 Dunn J Thabet S Jo H July 2015 Flow Dependent Epigenetic DNA Methylation in Endothelial Gene Expression and Atherosclerosis Arteriosclerosis Thrombosis and Vascular Biology 35 7 1562 9 doi 10 1161 ATVBAHA 115 305042 PMC 4754957 PMID 25953647 Dunn J Simmons R Thabet S Jo H October 2015 The role of epigenetics in the endothelial cell shear stress response and atherosclerosis The International Journal of Biochemistry amp Cell Biology 67 167 76 doi 10 1016 j biocel 2015 05 001 PMC 4592147 PMID 25979369 Boudreau N Andrews C Srebrow A Ravanpay A Cheresh DA October 1997 Induction of the angiogenic phenotype by Hox D3 The Journal of Cell Biology 139 1 257 64 doi 10 1083 jcb 139 1 257 PMC 2139816 PMID 9314544 Boudreau NJ Varner JA February 2004 The homeobox transcription factor Hox D3 promotes integrin alpha5beta1 expression and function during angiogenesis The Journal of Biological Chemistry 279 6 4862 8 doi 10 1074 jbc M305190200 PMID 14610084 Myers C Charboneau A Boudreau N January 2000 Homeobox B3 promotes capillary morphogenesis and angiogenesis The Journal of Cell Biology 148 2 343 51 doi 10 1083 jcb 148 2 343 PMC 2174277 PMID 10648567 Chen Y Xu B Arderiu G Hashimoto T Young WL Boudreau N et al November 2004 Retroviral delivery of homeobox D3 gene induces cerebral angiogenesis in mice Journal of Cerebral Blood Flow and Metabolism 24 11 1280 7 doi 10 1097 01 WCB 0000141770 09022 AB PMID 15545924 Myers C Charboneau A Cheung I Hanks D Boudreau N December 2002 Sustained expression of homeobox D10 inhibits angiogenesis The American Journal of Pathology 161 6 2099 109 doi 10 1016 S0002 9440 10 64488 4 PMC 1850921 PMID 12466126 Mace KA Hansen SL Myers C Young DM Boudreau N June 2005 HOXA3 induces cell migration in endothelial and epithelial cells promoting angiogenesis and wound repair Journal of Cell Science 118 Pt 12 2567 77 doi 10 1242 jcs 02399 PMID 15914537 Rhoads K Arderiu G Charboneau A Hansen SL Hoffman W Boudreau N 2005 A role for Hox A5 in regulating angiogenesis and vascular patterning Lymphatic Research and Biology 3 4 240 52 doi 10 1089 lrb 2005 3 240 PMID 16379594 a b Arderiu G Cuevas I Chen A Carrio M East L Boudreau NJ 2007 HoxA5 stabilizes adherens junctions via increased Akt1 Cell Adhesion amp Migration 1 4 185 95 doi 10 4161 cam 1 4 5448 PMC 2634105 PMID 19262140 Zhu Y Cuevas IC Gabriel RA Su H Nishimura S Gao P et al June 2009 Restoring transcription factor HoxA5 expression inhibits the growth of experimental hemangiomas in the brain Journal of Neuropathology and Experimental Neurology 68 6 626 32 doi 10 1097 NEN 0b013e3181a491ce PMC 2728585 PMID 19458547 Chen H Rubin E Zhang H Chung S Jie CC Garrett E et al May 2005 Identification of transcriptional targets of HOXA5 The Journal of Biological Chemistry 280 19 19373 80 doi 10 1074 jbc M413528200 PMID 15757903 Kadrmas JL Beckerle MC November 2004 The LIM domain from the cytoskeleton to the nucleus Nature Reviews Molecular Cell Biology 5 11 920 31 doi 10 1038 nrm1499 PMID 15520811 S2CID 6030950 Gruss P Walther C May 1992 Pax in development Cell 69 5 719 22 doi 10 1016 0092 8674 92 90281 G PMID 1591773 S2CID 44613005 Archived from the original on 2021 05 02 Retrieved 2019 12 11 Walther C Gruss P December 1991 Pax 6 a murine paired box gene is expressed in the developing CNS Development 113 4 1435 49 doi 10 1242 dev 113 4 1435 PMID 1687460 Burglin TR November 1997 Analysis of TALE superclass homeobox genes MEIS PBC KNOX Iroquois TGIF reveals a novel domain conserved between plants and animals Nucleic Acids Research 25 21 4173 80 doi 10 1093 nar 25 21 4173 PMC 147054 PMID 9336443 Derelle R Lopez P Le Guyader H Manuel M 2007 Homeodomain proteins belong to the ancestral molecular toolkit of eukaryotes Evolution amp Development 9 3 212 9 doi 10 1111 j 1525 142X 2007 00153 x PMID 17501745 S2CID 9530210 a b c d e Holland PW Booth HA Bruford EA October 2007 Classification and nomenclature of all human homeobox genes BMC Biology 5 1 47 doi 10 1186 1741 7007 5 47 PMC 2211742 PMID 17963489 Coulier F Popovici C Villet R Birnbaum D 15 December 2000 MetaHox gene clusters Journal of Experimental Zoology 288 4 345 351 doi 10 1002 1097 010X 20001215 288 4 lt 345 AID JEZ7 gt 3 0 CO 2 Y PMID 11144283 Kraus P Lufkin T July 2006 Dlx homeobox gene control of mammalian limb and craniofacial development American Journal of Medical Genetics Part A 140 13 1366 74 doi 10 1002 ajmg a 31252 PMID 16688724 S2CID 32619323 Further reading editLodish H Berk A Matsudaira P Kaiser CA Krieger M Scott MP et al 2003 Molecular Cell Biology 5th ed New York W H Freeman and Company ISBN 978 0 7167 4366 8 Tooze C Branden J 1999 Introduction to protein structure 2nd ed New York Garland Pub pp 159 66 ISBN 978 0 8153 2305 1 Ogishima S Tanaka H January 2007 Missing link in the evolution of Hox clusters Gene 387 1 2 21 30 doi 10 1016 j gene 2006 08 011 PMID 17098381 External links editThe Homeodomain Resource National Human Genome Research Institute National Institutes of Health HomeoDB a database of homeobox genes diversity Zhong YF Butts T Holland PWH since 2008 Archived 2021 06 01 at the Wayback Machine Eukaryotic Linear Motif resource motif class LIG HOMEOBOX Homeobox at the U S National Library of Medicine Medical Subject Headings MeSH This article incorporates text from the public domain Pfam and InterPro IPR001356 Retrieved from https en wikipedia org w index php title Homeobox amp oldid 1216726233, wikipedia, wiki, book, books, library,

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