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• 11:39, 21 November 2024 Rasbak talk contribs uploaded File:Differences in osteoblastogenesis and osteoclastogenesis.png ({{Information |Description=Figure 3. Differences in osteoblastogenesis and osteoclastogenesis. |Source=https://www.mdpi.com/2073-4409/12/21/2576 Šromová, V.; Sobola, D.; Kaspar, P. A Brief Review of Bone Cell Function and Importance. Cells 2023, 12, 2576. https://doi.org/10.3390/cells12212576 |Date=2023-11-05 |Author=Šromová, V.; Sobola, D.; Kaspar, P. A |Permission= |other_versions= }} {{Licensereview}} © 2023 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open acce...)
• 11:34, 21 November 2024 Rasbak talk contribs uploaded File:Osteoblast and osteoclast differentiation and life cycle before apoptosis.png ({{Information |Description=Figure 4. Osteoblast and osteoclast differentiation and life cycle before apoptosis. |Source=https://www.mdpi.com/2073-4409/12/21/2576 Šromová, V.; Sobola, D.; Kaspar, P. A Brief Review of Bone Cell Function and Importance. Cells 2023, 12, 2576. https://doi.org/10.3390/cells12212576 |Date=2023-11-05 |Author=Šromová, V.; Sobola, D.; Kaspar, P. A |Permission= |other_versions= }} {{Licensereview}} © 2023 by the authors. Licensee MDPI, Basel, Switzerland. This articl...)
• 11:31, 21 November 2024 Rasbak talk contribs uploaded File:Osteoclast sealing zone formation and proton transport.png ({{Information |Description=Figure 2. Osteoclast sealing zone formation and proton transport. |Source=https://www.mdpi.com/2073-4409/12/21/2576 Šromová, V.; Sobola, D.; Kaspar, P. A Brief Review of Bone Cell Function and Importance. Cells 2023, 12, 2576. https://doi.org/10.3390/cells12212576 |Date=2023-11-05 |Author=Šromová, V.; Sobola, D.; Kaspar, P. A |Permission= |other_versions= }} {{Licensereview}} © 2023 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open acces...)
• 11:14, 21 November 2024 Rasbak talk contribs uploaded File:PPARɑ-ß-ɣ activation induced peroxisome proliferation in calvarial osteoblasts.png ({{Information |Description=Fig 7. PPARɑ/ß/ɣ activation induced peroxisome proliferation in calvarial osteoblasts. (A-H) Primary osteoblasts were treated with vehicle (Vh, A, B) ciprofibrate (Cip, C), GW6471 (D), GW0742 (E), GSK0660 (F), troglitazone (Tro, G) and GW9662 (H) and were stained for PEX14. The strong immunoreactivity and homogenous distribution of PEX14 in individual peroxisomes indicates an increase in the peroxisome number (peroxisome proliferation) and not in PEX14 protein in e...)
• 11:07, 21 November 2024 Rasbak talk contribs uploaded File:The distribution of Pex11ß cRNA revealed the strongest expression in the mineralization areas of the cartilage and in osteoblasts of the calvaria of newborn mice.png ({{Information |Description=Fig 3. The distribution of Pex11ß cRNA revealed the strongest expression in the mineralization areas of the cartilage and in osteoblasts of the calvaria of newborn mice. (A-H) Higher magnifications of in situ hybridization preparations of Pex11ß cRNA in vertebrae (A), the calvaria (B), ribs (C, D), femur (F, G), and the mandible (H) are shown. The corresponding negative controls were hybridized with the complementary Pex11ß mRNA strand (I). Please note that the exp...)
• 11:05, 21 November 2024 Rasbak talk contribs uploaded File:Hypertrophic chondrocytes contained the highest numerical abundance of peroxisomes compared to proliferative chondrocytes as examples for endochondral ossification.png ({{Information |Description=Fig 2. Hypertrophic chondrocytes contained the highest numerical abundance of peroxisomes compared to proliferative chondrocytes as examples for endochondral ossification. (A-H) Immunofluorescence stainings of the peroxisomal membrane and matrix proteins PEX14 (A, B, G), catalase (C, D, H) and ABCD3 (E, F) were performed in paraffin-sections from the cartilage (A-D: vertebrae; E, F: femur growth plate; G, H: ribs) of 40-day (A-F) and P0.5 newborn (G, H) mice. Nucle...)
• 11:01, 21 November 2024 Rasbak talk contribs uploaded File:The highest abundance of peroxisomes was detected in osteoblast and osteoclast cells as examples for intramembranous and endochondral ossification.png ({{Information |Description=Fig 1. The highest abundance of peroxisomes was detected in osteoblast and osteoclast cells as examples for intramembranous and endochondral ossification. (A-B) Paraffin sections of the calvaria (A) and mandible (B) of newborn mice (P0.5) were stained with hematoxylin and eosin to give an overview on bone architecture and localization of osteoblasts (OB), osteocytes (OC) and osteoclasts (bold arrows). (C-H) Immunofluorescence stainings for PEX14 (C, E, G) and catal...)
• 10:53, 21 November 2024 Rasbak talk contribs uploaded File:New model for endochondral fracture repair local osteochondral progenitors from the periosteum and endosteum are the stem cells that differentiate to form bone and cartilage in the fracture.jpg ({{Information |Description=Figure 4. A new model for endochondral fracture repair: local osteochondral progenitors from the periosteum and endosteum are the stem cells that differentiate to form bone and cartilage in the fracture site. To generate the cartilage callus, osteochondral progenitors differentiate into chondrocytes (blue) that proliferate to generate the early soft callus. Chondrocytes within the callus mature into hypertrophic chondrocytes. Expression of angiogenic factors by thes...)
• 00:39, 21 November 2024 Rasbak talk contribs uploaded File:Sections of the tibial epiphysis of 19 day-old rats.png ({{Information |Description=Figure 2. Sections of the tibial epiphysis of 19 day-old rats. (A) Section stained with von Kossa and counterstained with toluidine blue showing that the epiphyseal bony tissue displays a “bicycle wheel” pattern at the upper portion and a bridge-like disposition at the lower portion. (B) Semithin section stained with toluidine blue showing rounded hollows (arrowheads) and ridges (arrows) in the epiphyseal cartilage. Boxed area is shown at a higher magnification in f...)
• 00:37, 21 November 2024 Rasbak talk contribs uploaded File:Sections of the tibial epiphysis at the beginning of epiphyseal bone formation Rat.png ({{Information |Description=Figure 1. Sections of the tibial epiphysis at the beginning of epiphyseal bone formation. (A) Semithin section stained with toluidine of a 3-day-old tibia showing a completely cartilaginous epiphysis. (B) Semithin section stained with toluidine of an 8-day-old tibia showing a cartilage canal (arrow) and the early secondary ossification center. (C) Semithin section stained with toluidine of an 11-day-old tibia showing a central rounded marrow cavity smoothly bordered...)
• 00:33, 21 November 2024 Rasbak talk contribs uploaded File:Sections of the tibial epiphysis of a 35 day-old rat.png ({{Information |Description=Figure 4. Sections of the tibial epiphysis of a 35 day-old rat. (A) Section stained with von Kossa showing that the epiphyseal bone plate and the underlying growth plate are bridged by a number of thin bony extensions. Boxed area is shown at a higher magnification in figure B. (B) Magnification of the boxed area in A showing a bone-cartilage contact. Note that osteocytes in the mineralized matrix are not aligned do not show a clear orientation. (C) SEM image showing...)
• 00:24, 21 November 2024 Rasbak talk contribs uploaded File:Sections of the tibial epiphysis of a 24-day-old rat.png ({{Information |Description=Figure 3. Sections of the tibial epiphysis of a 24-day-old rat. (A) Confocal microscopy showing a 3D projection reconstructed from z-stack images of bone tissue labeled with calcein. Fluorescence (green) is located around the blood vessels and this gives rise to an arrangement of circles whereas the underlying growth plate cartilage is completely devoid of fluorescence. (B) Semithin section stained with toluidine blue showing a continuous monolayer of cuboidal osteo...)
• 20:50, 20 November 2024 Rasbak talk contribs uploaded File:Transcriptional regulation of osteoblast differentiation.png ({{Information |Description=Figure 2. Transcriptional regulation of osteoblast differentiation. SOX9 and RUNX2 are major fate determinants of mesenchymal progenitors to chondrogenesis and osteoblastogenesis, respectively. Cells can “detour” to chondrogenesis or commit to an osteoblast lineage. RUNX2 is the master transcription factor that regulates multiple steps in osteoblast commitment and differentiation. Its transcriptional activity is controlled at multiple levels such as transcriptional...)
• 20:10, 20 November 2024 Rasbak talk contribs uploaded File:Current understanding of osteogenesis and bone remodeling.png ({{Information |Description=Figure 1. Current understanding of osteogenesis and bone remodeling. (A) Flat bones are formed through intramembranous ossification, cells are originated from the cranial neural crest (CNC). Limb bones are formed through endochondral ossification (details shown in (C)), cells are originated from the mesoderm-derived limb bud (LB) mesenchyme. (B) Two major routes for osteoblast differentiation. Mesoderm cells give rise to mesenchymal osteochondroprogenitors (OCPs) wh...)
• 15:35, 20 November 2024 Rasbak talk contribs uploaded File:The mechanisms for bone repair in the spine.png ({{Information |Description=Figure 2. The mechanisms for bone repair in the spine |Source=https://www.mdpi.com/2075-4426/14/9/957 Ge, R.; Liu, C.; Zhao, Y.; Wang, K.; Wang, X. Endochondral Ossification for Spinal Fusion: A Novel Perspective from Biological Mechanisms to Clinical Applications. J. Pers. Med. 2024, 14, 957. https://doi.org/10.3390/jpm14090957 |Date=2024-09-09 |Author=Ge, R.; Liu, C.; Zhao, Y.; Wang, K.; Wang, X. |Permission= |other_versions= }} {{Licensereview}} © 2024 by the...)
• 15:28, 20 November 2024 Rasbak talk contribs uploaded File:Intramembranous ossification and endochondral ossification.png ({{Information |Description=Figure 1. Intramembranous ossification and endochondral ossification |Source=https://www.mdpi.com/2075-4426/14/9/957 Ge, R.; Liu, C.; Zhao, Y.; Wang, K.; Wang, X. Endochondral Ossification for Spinal Fusion: A Novel Perspective from Biological Mechanisms to Clinical Applications. J. Pers. Med. 2024, 14, 957. https://doi.org/10.3390/jpm14090957 |Date=2024-09-09 |Author=Ge, R.; Liu, C.; Zhao, Y.; Wang, K.; Wang, X. |Permission= |other_versions= }} {{Licensereview}}...)
• 11:35, 20 November 2024 Rasbak talk contribs uploaded File:Planar cell polarity shaping of the early endochondral condensation.jpg ({{Information |Description=FIGURE 5. Planar cell polarity shaping of the early endochondral condensation. Schematic of FAT4-DCHS1 regulation of sternum morphogenesis. Cells with in-filled colors (red/yellow/orange/olive) serve as landmarks to compare time points. Initially, sternal cells are orientated along the rostral-caudal (R-C) axis. A gradient of DCHS1 (turquoise) and FAT4 (purple) across the medial-lateral (M-L) axis of the sternal mesenchyme results in higher levels of DCHS1 and FAT4...)
• 11:29, 20 November 2024 Rasbak talk contribs uploaded File:Mechanisms of intramembranous bone growth.jpg ({{Information |Description=FIGURE 6. Mechanisms of intramembranous bone growth. A, Mechanisms of intramembranous growth over time. A-D, Initially, ossifications expand by osteoblast proliferation. A,D,F, Then, in mammals and avians, secondary cartilage can develop. A,G,H, Once intramembranous bones meet, they also grow at sutures. B,E, Schematics of calvaria bone expansion and suture formation in a mouse embryo. At E14.5 (B), the frontal and parietal bones start to expand, the mesoderm that g...)
• 11:23, 20 November 2024 Rasbak talk contribs uploaded File:Development and an evolutionary modification of the ribs.jpg ({{Information |Description=FIGURE 4. Development and an evolutionary modification of the ribs. A, The sclerotome (encompassing the green, purple, and orange domains) is specified into distinct molecular domains within the somite in response to sonic hedgehog (SHH) and BMP4/WNT signals from the notochord/floor plate and roof plate, respectively. These different domains give rise to distinct parts of the vertebrae. At thoracic levels, the early outgrowth of the rib is specified within the scler...)
• 11:19, 20 November 2024 Rasbak talk contribs uploaded File:Development and elongation of endochondral bones.jpg ({{Information |Description=FIGURE 3. Development and elongation of endochondral bones. Phases of endochondral bone development: A, cell adhesion and ECM secretion (green lines); increased cell division may also occur, B, chondrocyte commitment and cartilaginous matrix production including collagen fibrils (blue), C, perichondrium formation, and D, establishment of the chondrocyte zones and articular cartilage. Proliferation occurs in the reserve zone, proliferating and prehypertrophic zones;...)
• 11:12, 20 November 2024 Rasbak talk contribs uploaded File:The embryonic origin of human bones.jpg ({{Information |Description=FIGURE 2. The embryonic origin of human bones. Schematic showing the proposed embryonic origin of bones from the paraxial mesoderm (blue), lateral plate mesoderm (brown), and neural crest cells (yellow) in humans based on fate mapping studies in the mouse and chick described in References 57-62, (also see review for scapula and pelvis63, 76, 290). The arytenoid cartilage (not shown) also arises from the lateral plate mesoderm.60, 62 For clarity, the NCC and mesoderm...)
• 11:09, 20 November 2024 Rasbak talk contribs uploaded File:The chondrocyte and osteoblast differentiation pathways.jpg ({{Information |Description=FIGURE 1. The chondrocyte and osteoblast differentiation pathways. Simplified schematic showing the key genes that are expressed during chondrogenic and osteoblastic differentiation and the relationship between the two lineages. In hypertrophic chondrocytes, the expression of SOX9 protein persists in early hypertrophic chondrocytes where SOX9 induces the expression of Collagen type X and inhibits RUNX2 activity. Degradation of SOX9 protein releases inhibition of RUN...)
• 01:01, 20 November 2024 Rasbak talk contribs performed unknown action "create/create" on Category:Endochondral ossification (←Created page with 'Category:Ossification')
• 00:57, 20 November 2024 Rasbak talk contribs performed unknown action "create/create" on File:Schematic of endochondral ossification and formation of primary and secondary ossification centers.jpg ({{Information |Description=Figure 1. Schematic of endochondral ossification and formation of primary and secondary ossification centers. |Source= Javaheri B, Caetano-Silva SP, Kanakis I, Bou-Gharios G and Pitsillides AA (2018) The Chondro-Osseous Continuum: Is It Possible to Unlock the Potential Assigned Within? Front. Bioeng. Biotechnol. 6:28. doi: 10.3389/fbioe.2018.00028 |Date=2018-03-21 |Author=Javaheri B, Caetano-Silva SP, Kanakis I, Bou-Gharios G and Pitsillides AA |Permission= |other_...)
• 00:57, 20 November 2024 Rasbak talk contribs uploaded File:Schematic of endochondral ossification and formation of primary and secondary ossification centers.jpg ({{Information |Description=Figure 1. Schematic of endochondral ossification and formation of primary and secondary ossification centers. |Source= Javaheri B, Caetano-Silva SP, Kanakis I, Bou-Gharios G and Pitsillides AA (2018) The Chondro-Osseous Continuum: Is It Possible to Unlock the Potential Assigned Within? Front. Bioeng. Biotechnol. 6:28. doi: 10.3389/fbioe.2018.00028 |Date=2018-03-21 |Author=Javaheri B, Caetano-Silva SP, Kanakis I, Bou-Gharios G and Pitsillides AA |Permission= |other_...)
• 21:44, 19 November 2024 Rasbak talk contribs performed unknown action "create/create" on Category:Osteoprogenitors (←Created page with 'Category:Bone cells')
• 21:44, 19 November 2024 Rasbak talk contribs performed unknown action "create/create" on Category:Osteocyts (←Created page with 'Category:Bone cells')
• 18:15, 17 November 2024 Rasbak talk contribs performed unknown action "create/create" on File:The effect of bacterial inoculation on proteolytic skin maceration and on no treatment skin. Rat.png ({{Information |Description= Fig 2. The effect of bacterial inoculation on proteolytic skin maceration and on no treatment skin. Rat. (a) Macroscopic skin appearance of proteolytic skin maceration inoculated with bacteria. Skin appearance was observed immediately after removal of filter paper soaked with bacterial suspension (left side), and also at 24 h after bacterial inoculation (right side). The upper half of each photograph is the treatment area. Immediately after treatment, no macroscop...)
• 18:15, 17 November 2024 Rasbak talk contribs uploaded File:The effect of bacterial inoculation on proteolytic skin maceration and on no treatment skin. Rat.png ({{Information |Description= Fig 2. The effect of bacterial inoculation on proteolytic skin maceration and on no treatment skin. Rat. (a) Macroscopic skin appearance of proteolytic skin maceration inoculated with bacteria. Skin appearance was observed immediately after removal of filter paper soaked with bacterial suspension (left side), and also at 24 h after bacterial inoculation (right side). The upper half of each photograph is the treatment area. Immediately after treatment, no macroscop...)
• 18:13, 17 November 2024 Rasbak talk contribs performed unknown action "create/create" on File:Healing process of tissue damage and bacterial cluster in proteolytic skin maceration. Rat.png ({{Information |Description= Fig 3. Healing process of tissue damage and bacterial cluster in proteolytic skin maceration. (a) Skin appearance was observed every day from day 1 to 6. The area of skin redness became larger, and redness got stronger over time until day 3. The redness faded after day 3 and returned to normal. Scale bar = 1 cm. Histological changes in proteolytic skin maceration were observed on day 2 (b, c) and day 3 (e-m). Thin sections were stained with HE (b, e, f, g), with i...)
• 18:13, 17 November 2024 Rasbak talk contribs uploaded File:Healing process of tissue damage and bacterial cluster in proteolytic skin maceration. Rat.png ({{Information |Description= Fig 3. Healing process of tissue damage and bacterial cluster in proteolytic skin maceration. (a) Skin appearance was observed every day from day 1 to 6. The area of skin redness became larger, and redness got stronger over time until day 3. The redness faded after day 3 and returned to normal. Scale bar = 1 cm. Histological changes in proteolytic skin maceration were observed on day 2 (b, c) and day 3 (e-m). Thin sections were stained with HE (b, e, f, g), with i...)
• 11:42, 17 November 2024 Rasbak talk contribs performed unknown action "create/create" on Category:Skin maceration (←Created page with 'Category:Diseases and disorders of the skin')
• 11:38, 17 November 2024 Rasbak talk contribs performed unknown action "create/create" on File:Comparison of proteolytic skin maceration and no treatment skin.tif ({{Information |Description= Fig 1. Comparison of proteolytic skin maceration and no treatment skin. (a) Macroscopic skin appearance of proteolytic skin maceration. Skin appearance was observed at both 30 min (left side) and 24 h (right side) after removal of agarose gels. The upper half of both panels is the macerated area. At 24 h after treatment, flare and dot-like redness (black arrowheads) were observed in PT skin. No erosion was observed in either group. Scale bar = 1 cm. (b-j) Histolog...)
• 11:38, 17 November 2024 Rasbak talk contribs uploaded File:Comparison of proteolytic skin maceration and no treatment skin.tif ({{Information |Description= Fig 1. Comparison of proteolytic skin maceration and no treatment skin. (a) Macroscopic skin appearance of proteolytic skin maceration. Skin appearance was observed at both 30 min (left side) and 24 h (right side) after removal of agarose gels. The upper half of both panels is the macerated area. At 24 h after treatment, flare and dot-like redness (black arrowheads) were observed in PT skin. No erosion was observed in either group. Scale bar = 1 cm. (b-j) Histolog...)
• 15:26, 16 November 2024 Rasbak talk contribs performed unknown action "create/create" on File:The developing funnelsiphon organ shows limb-like expression patterns of the proximodistal patterning genes Exd and Wnt5. Sepia officinalis.jpg ({{Information |Description= Figure 5—figure supplement 1. The developing funnel/siphon organ shows limb-like expression patterns of the proximodistal patterning genes Exd and Wnt5. ''Sepia officinalis'' (A-D) OPT reconstructions of stage 17 to 24 cuttlefish embryos showing the developing funnel/siphon system (pseuodocolored red). (A) Funnel development begins at stage 17 with emergence of two bilaterally symmetrical funnel ridges between the row limb buds (bottom) and the gill primordia (GP)...)
• 15:26, 16 November 2024 Rasbak talk contribs uploaded File:The developing funnelsiphon organ shows limb-like expression patterns of the proximodistal patterning genes Exd and Wnt5. Sepia officinalis.jpg ({{Information |Description= Figure 5—figure supplement 1. The developing funnel/siphon organ shows limb-like expression patterns of the proximodistal patterning genes Exd and Wnt5. ''Sepia officinalis'' (A-D) OPT reconstructions of stage 17 to 24 cuttlefish embryos showing the developing funnel/siphon system (pseuodocolored red). (A) Funnel development begins at stage 17 with emergence of two bilaterally symmetrical funnel ridges between the row limb buds (bottom) and the gill primordia (GP)...)
• 15:17, 16 November 2024 Rasbak talk contribs performed unknown action "create/create" on File:Molecular patterning of the anteroposterior, proximodistal, and dorsoventral axes of developing limbs in vertebrates, arthropods, and cephalopods.jpg ({{Information |Description= Figure 5.Molecular patterning of the anteroposterior, proximodistal, and dorsoventral axes of developing limbs in vertebrates, arthropods, and cephalopods. For each lineage, the top row shows schematic representations of a generalized limb bud and an adult limb in two different orientations. Axes are indicated to the left of each limb bud (A, anterior; Po, posterior; Pr, proximal; Di, distal; Do, dorsal; Ve, ventral) Bottom rows show limb buds with gene expression...)
• 15:17, 16 November 2024 Rasbak talk contribs uploaded File:Molecular patterning of the anteroposterior, proximodistal, and dorsoventral axes of developing limbs in vertebrates, arthropods, and cephalopods.jpg ({{Information |Description= Figure 5.Molecular patterning of the anteroposterior, proximodistal, and dorsoventral axes of developing limbs in vertebrates, arthropods, and cephalopods. For each lineage, the top row shows schematic representations of a generalized limb bud and an adult limb in two different orientations. Axes are indicated to the left of each limb bud (A, anterior; Po, posterior; Pr, proximal; Di, distal; Do, dorsal; Ve, ventral) Bottom rows show limb buds with gene expression...)
• 15:10, 16 November 2024 Rasbak talk contribs performed unknown action "create/create" on File:Analysis of gene expression in the arms and tentacles of Sepia bandensis embryos. Sepia officinalis.jpg ({{Information |Description=Figure 3—figure supplement 2.Analysis of gene expression in the arms and tentacles of ''Sepia bandensis'' embryos. S. bandensis probes that were used on S. officinalis embryos were validated by species-specific hybridization using S. bandensis embryos. Each probe yielded identical patterns of expression in the limb buds of the two Sepia species. (A–C) Stage 20 S. bandensis limb buds show proximodistally regionalized expression of Hth, Dll and Sp8/9a. The Hth domain...)
• 15:10, 16 November 2024 Rasbak talk contribs uploaded File:Analysis of gene expression in the arms and tentacles of Sepia bandensis embryos. Sepia officinalis.jpg ({{Information |Description=Figure 3—figure supplement 2.Analysis of gene expression in the arms and tentacles of ''Sepia bandensis'' embryos. S. bandensis probes that were used on S. officinalis embryos were validated by species-specific hybridization using S. bandensis embryos. Each probe yielded identical patterns of expression in the limb buds of the two Sepia species. (A–C) Stage 20 S. bandensis limb buds show proximodistally regionalized expression of Hth, Dll and Sp8/9a. The Hth domain...)
• 15:05, 16 November 2024 Rasbak talk contribs performed unknown action "create/create" on File:Expression of developmental control genes in cuttlefish limb buds.jpg ({{Information |Description=Figure 3—figure supplement 1. Expression of developmental control genes in cuttlefish limb buds. (A to O) In situ hybridizations showing Wnt1, Wnt5, Wnt7, Tcf, Exd, Hth, Dll, Dac, Sp8, Hh, Ptc, Bmp2/4, En and Sfrp1/2/5 in stage 21 embryos. Hh expression in stage 21 limb buds, detected by in situ hybridizations in whole mount (F) and cryosections (K) showing the central expression in the brachial nerve cell precursors. (P to R) In situ hybridizations of Frz9/10 at s...)
• 15:05, 16 November 2024 Rasbak talk contribs uploaded File:Expression of developmental control genes in cuttlefish limb buds.jpg ({{Information |Description=Figure 3—figure supplement 1. Expression of developmental control genes in cuttlefish limb buds. (A to O) In situ hybridizations showing Wnt1, Wnt5, Wnt7, Tcf, Exd, Hth, Dll, Dac, Sp8, Hh, Ptc, Bmp2/4, En and Sfrp1/2/5 in stage 21 embryos. Hh expression in stage 21 limb buds, detected by in situ hybridizations in whole mount (F) and cryosections (K) showing the central expression in the brachial nerve cell precursors. (P to R) In situ hybridizations of Frz9/10 at s...)
• 15:01, 16 November 2024 Rasbak talk contribs performed unknown action "create/create" on File:Expression of proximal identity genes Exd and Hth in arms and tentacles corresponds with distribution of suckers; Wnt signaling repressors are dorsally restricted Sepia officinalis.jpg ({{Information |Description=Figure 1Expression of proximal identity genes Exd and Hth in arms and tentacles corresponds with distribution of suckers; Wnt signaling repressors are dorsally restricted. (A and B) Compared to arms (A), tentacles (B) show a distally expanded domain of Exd expression in the proximal region of the limb. (C and D) A similar pattern of expression is detected for Hth during arm (C) and tentacle (D) development. Distal boundary of Exd and Hth expression marked by black...)
• 15:01, 16 November 2024 Rasbak talk contribs uploaded File:Expression of proximal identity genes Exd and Hth in arms and tentacles corresponds with distribution of suckers; Wnt signaling repressors are dorsally restricted Sepia officinalis.jpg ({{Information |Description=Figure 1Expression of proximal identity genes Exd and Hth in arms and tentacles corresponds with distribution of suckers; Wnt signaling repressors are dorsally restricted. (A and B) Compared to arms (A), tentacles (B) show a distally expanded domain of Exd expression in the proximal region of the limb. (C and D) A similar pattern of expression is detected for Hth during arm (C) and tentacle (D) development. Distal boundary of Exd and Hth expression marked by black...)
• 14:55, 16 November 2024 Rasbak talk contribs performed unknown action "create/create" on Category:Phylogenetic trees of hedgehog (←Created page with 'Category:Phylogenetic trees')
• 14:54, 16 November 2024 Rasbak talk contribs performed unknown action "create/create" on File:Hedgehog phylogeny.jpg ({{Information |Description=Figure 2—figure supplement 9. Hedgehog phylogeny. ''Sepia officinalis'' Molecular phylogenetic reconstruction using maximum likelihood implemented in RAxML of Hh ligand previously isolated (Tarazona et al., 2016) in this study. The arrow marks the phylogenetic placement of cuttlefish Hh sequence. |Source=https://elifesciences.org/articles/43828 Oscar A Tarazona Davys H Lopez Leslie A Slota Martin J Cohn (2019) Evolution of limb development in cephalopod mollusks e...)
• 14:54, 16 November 2024 Rasbak talk contribs uploaded File:Hedgehog phylogeny.jpg ({{Information |Description=Figure 2—figure supplement 9. Hedgehog phylogeny. ''Sepia officinalis'' Molecular phylogenetic reconstruction using maximum likelihood implemented in RAxML of Hh ligand previously isolated (Tarazona et al., 2016) in this study. The arrow marks the phylogenetic placement of cuttlefish Hh sequence. |Source=https://elifesciences.org/articles/43828 Oscar A Tarazona Davys H Lopez Leslie A Slota Martin J Cohn (2019) Evolution of limb development in cephalopod mollusks e...)
• 14:49, 16 November 2024 Rasbak talk contribs performed unknown action "create/create" on Category:Phylogenetic trees of Tgfβ (←Created page with 'Category:Transforming growth factor (TGF)-beta')
• 14:48, 16 November 2024 Rasbak talk contribs performed unknown action "create/create" on File:Tgfβ phylogeny.jpg ({{Information |Description=Figure 2—figure supplement 8. Tgfβ phylogeny. ''Sepia officinalis'' Molecular phylogenetic reconstruction using maximum likelihood implemented in RAxML of Tgfβ family ligands isolated in this study. The arrow marks the phylogenetic placement of cuttlefish Bmp2/4. |Source=https://elifesciences.org/articles/43828 Oscar A Tarazona Davys H Lopez Leslie A Slota Martin J Cohn (2019) Evolution of limb development in cephalopod mollusks eLife 8:e43828. https://doi.org/10....)
• 14:48, 16 November 2024 Rasbak talk contribs uploaded File:Tgfβ phylogeny.jpg ({{Information |Description=Figure 2—figure supplement 8. Tgfβ phylogeny. ''Sepia officinalis'' Molecular phylogenetic reconstruction using maximum likelihood implemented in RAxML of Tgfβ family ligands isolated in this study. The arrow marks the phylogenetic placement of cuttlefish Bmp2/4. |Source=https://elifesciences.org/articles/43828 Oscar A Tarazona Davys H Lopez Leslie A Slota Martin J Cohn (2019) Evolution of limb development in cephalopod mollusks eLife 8:e43828. https://doi.org/10....)