User talk:AshleyCal/sandbox
Jamie and I are going to add to the palatoquadrate article by creating the sections: evolution, embryonic development, function, and then by going into the differences in vertebrates. The function of the palatoquadrate will be discussed in a general section, which will also define what the palatoquadrate is and what it is made of. The evolution section will discuss how the palatoquadrate has formed over tim Jamie and I are going to add to the palatoquadrate article by creating the sections: evolution, embryonic development, function, and then by going into the differences in vertebrates. The function of the palatoquadrate will be discussed in a general section, which will also define what the palatoquadrate is and what it is made of. The evolution section will discuss how the palatoquadrate has formed over time. Embryonic development will be about how the palatoquadrate forms in vertebrates of the present time. The different vertebrates will each have their own section to display different functions and growth of the palatoquadrate. Embryonic development will be about how the palatoquadrate forms in vertebrates of the present time. The different vertebrates will each have their own section to display different functions and growth of the palatoquadrate.
References:
[2] [3] AshleyCal (talk) 17:00, 13 October 2016 (UTC) Ashleycal
Feather Development
[edit]Evolution of Feathers/Evolutionary origins Feathers are sometimes referred to as “elaborate reptile scales” just as birds are sometimes viewed as a subset of reptiles instead of their won category. Although this is a simplification, it originates from bird’s homology with reptiles. Birds evolved from fast bipedal dinosaurs, but feathers evolved before them, and not for flying as what was originally thought. This theory unraveled in the 1970’s when theropod dinosaurs (some common theropods were Tyrannusaurus rex and velociraptors) were discovered to have feathers. By looking at melanosomes, which are structures whose shape and arrangement determines how light reflects off of the pigment, in dinosaur fossils, scientists have found that dinosaurs did in fact have bold plumage. Specifically, Jakob Vinter and his colleagues analyzed the melanosomes in Anchiornis huxleyi, which they were able to reconstruct into what the plumage would have looked like 150 million years ago when A. huxleyi lived (Zimmer, 2016).
In 1861, a group of German quarry workers found the fossil of Archaeopteryx, which had feathers like modern birds, but also teeth in its mouth, a long, bony wing, and claws on its wings like a reptile. Archaeopteryx seems to be a transitionary animal from reptile to bird. However, Archaeopteryx had already rather developed feathers, which didn’t help to show how the feathers had evolved in the first place. In 1996, the missing fossil to help show the evolution of feathers was found. Sinosauropteryx was covered in thin, hollow filaments that covered its back and tail. Now, after finding many dinosaurs with primitive feathers, it is believed that feathers started out as these thin, hollow filaments, and eventually evolved into the fluffy coats of feathers seen on modern birds (Xu, 2008). There are a few theories for the reasons feathers evolved in the first place, if not for flight. The first is that they served a purpose as insulation. Theropods have been found covering their nests with their forelimbs, thought to be sheltering their young. Feathers known to be found on theropods would have played an important role for insulation. Another popular theory is that quick, bipedal dinosaurs used their feathers to run faster. It’s possible that the feathers assisted the dinosaurs running up inclines, and this advantage of speed eventually lead to flight. The arboreal theory suggests that animals that lived in trees found it quicker and more energy efficient to leap from tree to tree instead of running down a tree, across the ground to another tree, and back up the new tree. This leaping eventually lead to gliding, and flight (Kardong, 2015).
Another newer theory is that feathers were selected for sexually (Zimmer, 2016). Their bold plumage with its patterns, coloration, and even iridescent colors were to attract the opposite sex, which is very common in modern birds today. By uncovering new technology to look and analyze well-preserved melanosomes, scientists can reconstruct what the feathers on fossilized dinosaurs would have looked like, and they look rather flamboyant. More current theories of the original purpose/advantage of flight involve more than one of these theories in combination with each other. Ken Dial, a flight researcher at the University of Montana-Missoula, shows how chicks often use feathers to gain traction as it runs from predators up inclines, but this flapping also helps the chick steady itself as it goes down again (Zimmer, 2016). It is very possible that feathers had multiple useful functions first, before flight.
Feather Development Steps
Feathers begin to form from feather follicles, which are invaginations starting in the epidermis down to the dermis. It is in the dermis that the follicle and the pulp cavity begin to form the feather. The pulp cavity is the space that contains the hair follicle. The feather filament soon grows out of the follicle; this is due to cell proliferation, which is a increased number of cells as a result cell growth and division, at the follicle bass. These new cells form three different tissues. There is the sheath, which is the main feather tissues and pulp caps. The sheath is the supportive layer that surrounds the feather, which falls off as it grows. Similarly, the pulp caps, which protect the dermal core, also fall off as the feather grows. The main feather tissues later unfurl, which causes the disposal of the sheath and the pulp caps as it assumes its functional shape. As the feather grows, its spathe continues to form. When spathe is finished developing, the calamus begins to form within the base of the spathe. The calamus is the quill of the feather, which is the bottom portion that stays mainly within the pulp cavity. From there, the feather is fully developed and will remain as such until molting occurs, causing it to fall off. (Kardong, 2015)
Labeled Pictures
Types of Feathers
There are six different types of feathers, which are contour, flight, down, filoplumes, semiplumes, and bristle feathers. Pennaceous feathers, more commonly known as contour feathers, which splits into two groups; one group is symmetrical and covers the body and the other is the flight feathers. Contour feathers allow for protection from the elements. Flight feathers are long and asymmetrical; the asymmetry allows for stiffening of the rachis. The flight feathers of the wing are remiges; those located on the tail are rectrices. Flight feathers are separated into three separate groups--primary, secondary and tertiary. The primaries are at the far end of the wing and provide the forward thrust during takeoff and flight. The secondaries form a majority of the wing in the middle. The wings located closest to the body are the tertiaries. Plumulaceous feathers, otherwise known as down feathers, lack a rachis and barbs that interact. Normally, they are fluffy and use for insulation. There are special types of down feathers that, when disintegrated, can form keratin powder, which can be used waterproof feathers. Filoplumes are very thin, hair-like feathers with very few barbs. They are thought to have a sensory function; any other details are mostly unknown. Semiplumes have a very large central rachis and loose veins. This structure allows them to be used in insulation and aerodynamics. Bristle feathers have a very stiff rachis but few barbs. They are located around the eyes and mouth; it is believed that they have a protective and sensory function. (Drs. Foster, Smith)
Thompson, Mya. "Everything You Need To Know About Feathers." Bird Academy. N.p., 2014. Web. 26 Oct. 2016.
Prum, Richard. JOURNAL OF EXPERIMENTAL ZOOLOGY (MOL DEV EVOL) 285:291–306 (1999) Development and Evolutionary Origin of Feathers(n.d.): n. pag. JOURNAL OF EXPERIMENTAL ZOOLOGY. Yale University, 1999. Web.
Kardong, K. V. (2015). Vertebrates: Comparative anatomy, function, evolution (7th ed.). New York, NY: McGraw-Hill Education.
Foster, Dr., & Smith, Dr. (n.d.). Bird Feather Types, Anatomy, Growth, Color, and Molting. Retrieved November 09, 2016, from http://www.peteducation.com/article.cfm?c=15 1829&aid=2776
Xu, Zing. "A New Feather Type in a Nonavian Theropod and the Early Evolution of Feathers." A New Feather Type in a Nonavian Theropod and the Early Evolution of Feathers. PNAS, 7 Oct. 2008. Web. 13 Nov. 2016.
Zimmer, Carl. "The Tangled Bank: An Introduction to Evolution." Barnes & Noble. N.p., n.d. Web.
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AshleyCal (talk) 15:09, 27 October 2016 (UTC)Ashleycal
- ^ "FishFace | FaceBase." FishFace | FaceBase. University of Southern California, n.d. Web. 13 Oct. 2016.
- ^ Kardong, Kenneth V. Vertebrates: Comparative Anatomy, Function, Evolution. New York: McGraw Hill, NY. Print.
- ^ Knight, Jonathan. "ZFIN Anatomy Ontology: Palatoquadrate Cartilage." ZFIN Anatomy Ontology: Palatoquadrate Cartilage. University of Oregon, 02 June 2015. Web. 13 Oct. 2016.
- ^ Thompson, Mya. "Everything You Need To Know About Feathers." Bird Academy. N.p., 2014. Web. 26 Oct. 2016.
- ^ Prum, Richard. JOURNAL OF EXPERIMENTAL ZOOLOGY (MOL DEV EVOL) 285:291–306 (1999) Development and Evolutionary Origin of Feathers(n.d.): n. pag. JOURNAL OF EXPERIMENTAL ZOOLOGY. Yale University, 1999. Web.