Carl Friedrich Gauss: (1777, Brauschweig - 1855, Göttingen)

1. Carl Friedrich Gauss:(1777, Brauschweig - 1855, Göttingen) 生命綿延的數學性: 另一種思維習慣 (德語世界的科學事件之一) • 高斯 • 數學是科學的皇后 • 狐狸的足跡 For lecture only; BC Yang

2. Johann MENDEL (der Vorname Gregor wurde ihm nach seinem Eintritt ins Kloster verliehen), geb. 1822 in Heinzendorf (im deutschen Teil des damals österreichischen Schlesiens), Abt in Brünn, gest. 1884, publizierte 1866 (?) eine zwar kleine aber inhaltsschwere Schrift mit dem Titel “VERSUCHE ÜBER PFLANZEN-HYBRIDEN. For lecture only; BC Yang

3. In the Footsteps of Mendelby Margaret Hermánek PeasleeProfessor of Biology and Vice President for Academic AffairsUniversity of Pittsburgh at Titusville http://www.mendelweb.org/MWpeaslee.html

4. 孟德爾的花園 • 他想要回答什麼問題 ? • 為什麼結果被埋沒近 (35) 年? • 是什麼認知環境，讓後人了解到孟德爾研究的重要性? 1865+35=1900  "gelb x gelb = grün ...wenigstens manchmal" For lecture only; BC Yang

5. 很完整的討論: http://www.weloennig.de/mendel.htm • Warum seine Entdeckungen 35 (72?) Jahre ignoriert wurden • Ein paar kritische Kommentare von Pionieren der Genetik sowie weiteren Biologen und Biologiehistorikern zur Wirkung des Darwinismus auf die biologische Forschung • Why his discoveries were ignored for 35 (72) years • Some critical comments about the effects of Darwinism on Biological Research by Pioneers of Genetics as well as further Biologists and Historians of Biology (German with English Summary) For lecture only; BC Yang

6. A link between the study of natural disciplines, such as botany and zoology, and physics had already been expressed by Andreas Baumgartner (1793-1865), professor of Physics at the University of Vienna until 1864, who acted as examiner for Mendel in Brno in 1850. Baumgartner had been so impressed by Mendel, that he suggested to Abbot Napp that the young monk should be sent to the University of Vienna. Professor Baumgartner emphasized the importance of studying nature, not through random speculation but through experiments theoretically underpinned by mathematical models. For lecture only; BC Yang

7. 孟德爾的老師 Andreas Baumgartner(1793 - 1865) • In 1823 he lectured at Vienna university, published his works as well as a Magazine of physics and mathematics, and wrote a book of elementary physics. • A native of  Frymburk in the Český Krumlov region. For lecture only; BC Yang

8. 孟德爾的老師 • Franz Unger (1800-1870) : about Evolution (1852, Wien), test how variation is formed (How to do this?). • Darwin published “On the origin of species: in 1859 • 1869, Mendel had talked about evolution, and sent a copy of paper to Darwin. • Christian Doppler (1803-1853 ): on physics. For lecture only; BC Yang

9. http://www.gmi.oeaw.ac.at/institut2geschichte.htm For lecture only; BC Yang

10. F. Jahn Ed. Lucas, J. Oberdieck Illustriertes Handbuch der Obstkunde (Stuttgart, Verlag von Ebner & Zeubert, 1859 sq) vol. I (Birne-1860) p. 355, Comparison of seed disposition in pears.Brno, Library of the Abbey of St Thomas 這是孟德爾讀過的書吧 http://www.mendel-museum.org/ For lecture only; BC Yang

11. 孟德爾還知道哪些事? • Atomic theory by John Dalton (1766-1844). • 可能知道 Statistic 嗎? http://falcon.sbuniv.edu/~ggray.wh.bol/CHE1104/pcp3outl.html Father of epidemiology: John Snow: 1813-1859 For lecture only; BC Yang

12. http://www.weloennig.de/mendel.htm • After two lectures in 1865, Mendel published his famous Pisum-treatise VERSUCHE ÜBER PFLANZEN-HYBRIDEN in 1866. His work was quoted at least 14 times before 1900, the year of its 'rediscovery'. There were references in such widely distributed works as Focke's DIE PFLANZEN-MISCHLINGE (1881), THE ENCYCLOPAEDIA BRITANNICA (1881) and the CATALOGUE OF SCIENTIFIC PAPERS OF THE ROYAL SOCIETY (1879). The treatise had been sent to the libraries of some 120 institutions including the Royal and Linnean Society of Great Britain. Moreover Mendel had 40 additional reprints at his disposal, many of which he sent to leading biologists of Europe. In fact, professor Niessl (1903 and 1906) emphasized that Mendel's work was "well known" at his time. For lecture only; BC Yang

13. 是什麼東西引起孟德爾如此大的興趣，讓他願意花費八(?)年時間進行植物雜交實驗?是什麼東西引起孟德爾如此大的興趣，讓他願意花費八(?)年時間進行植物雜交實驗? 在費曼之前 – 二十世紀的科學簡史; 陳恒安譯, 究竟, 台北 (2002). Ernst Peter Fischer (1995), Einstein & Co.: Eine kleine Geschichte der Wissenschaft der letzten hundert Jahre in Porträts. • 或者他只是無聊找事做? For lecture only; BC Yang

14. Mendel's green pea (Pisum sativum), is also called the garden pea or English pea. For lecture only; BC Yang

15. 孟德爾用的工具吧 • A. List of seedsordered by Mendel to Ernst Benary for the Abbey, 2nd November 1878, and a bill from the seed firm, Bestell Nota Herrn Ernst Benary in Erfurt..Brno, Abbey of St Thomas • B. Grafting and pruning tools in wooden box, Dittmar Keilbronn Brno, Abbey of St Thomas B A http://www.mendel-museum.org/eng/1online/room1.htm For lecture only; BC Yang

16. Mendel‘s green pea (這是錯!的說法) D R D R Seed shape Seed color Flower position Flower color 應該是子葉的顏色 Pot shape Pot color Stem high http://ridge.icu.ac.jp/gen-ed/mendel-gifs/03-mendel-characters2.JPG For lecture only; BC Yang

17. http://www.giddings.txed.net/biology/ch12.html 就是這樣做 So ist es gemacht! For lecture only; BC Yang

18. Mendelregeln • 1. Uniformitätsregel (顯隱律): • Kreuzt man zwei Individuen einer Art, die sich nur in einem Merkmal unterscheiden und in Bezug auf dasselbe homozygot sind, so sind die Individuen der Tochtergeneration (F1) im betrachteten Merkmal gleich, d.h. uniform. Alle Individuen der Tochtergeneration haben nicht nur denselben Phänotypus, sondern auch denselben Genotypus. Dies trifft sowohl beim intermediären als auch beim dominanten Erbgang zu. • 2. Spaltungsregel (分離律): • Kreuzt man Individuen der F1- Generation unter sich weiter, so kommt es zu einem Aufspalten der Merkmale. Vom Phänotypus findet das Aufspalten beim intermediären Erbgang im Verhältnis 1:2:1 statt, beim dominanten im Verhältnis 1:3. Der Genotypus tritt in beiden Erbgängen im Verhältnis 1:2:1 auf. • 3. Regel von der Unabhängigkeit der Erbanlagen (獨立分配律): • Kreuzt man zwei Individuen einer Art, die sich in zwei Merkmalen unterscheiden und in Bezug auf dieselben homozygot sind, so findet man in der F2- Generation eine Aufspaltung der Merkmale im Verhältnis 9:3:3:1 beim dominanten Erbgang. Dies beweist, dass die Gene unabhängig voneinander vererbt werden und frei kombinierbar sind. For lecture only; BC Yang

19. When Mendel's paper was published, in 1866, it received little attention, and was rarely cited by botanists or biologists during the next 34 years. Mendel's work has been thought to exemplify everything from the failure of traditional modes of scientific communication (Bush [1945]) to the phenomenon of "premature scientific discovery" ( Stent [1978]). In 1900, Mendel's work was cited by three botanists, writing in different parts of Europe: Hugo de Vries, in Amsterdam; Carl Correns, in Tübingen; and Eric Von Tcshermak, in Esslingen, Austria. Although their interpretations of what Mendel had shown were arguably inaccurate, these citations caused what has come to be known as the "rediscovery" of Mendel. For lecture only; BC Yang http://www.mendelweb.org/MWhartl.intro.html

20. Two stories • A fellow Dutch scientist, Professor Beyerinck of Delft, knew that de Vries had been hybridizing plants and wrote asking if he would be interested in an old reprint dealing with the same subject. It was Mendel’s “Versuche über Pflanzen Hybriden”, which reached de Vries in 1990, just as he was preparing to publish his own experiments. • In the autumn of 1899 the solution came to Correns in a “blind flash”, which seems to be the origin of the truly important breakthroughs in science. A short time later he found a reference to Mendel’s paper and looked it up. He published his own data and showed how it confirmed what Mendel had found. Summary by Moore JA, 1993, in: Science as a way of Knowing, The foundations of modern biology. p286 Moore也把 Eric Von Tcshermak的貢獻忽略了! For lecture only; BC Yang

21. 也是八年 Nägeli 做這個 • Correns was a tutor at the University of Tübingen when he began to experiment with trait inheritance in plants in 1892. Correns already knew about some of Mendel's hawkweed plant experiments from Nägeli. Nägeli, however, never talked about Mendel's key pea plant results, so Correns was initially unaware of Mendel's laws of heredity. • However, by 1900, when Correns submitted his own results for publication, the paper was called: G. Mendel's Law Concerning the Behavior of the Progeny of Racial Hybrids. • Correns and de Vries were the ones who most clearly "redefined" Mendel's laws. Correns (with credit to de Vries) restated Mendel's results, giving us Mendel's law of segregation and Mendel's law of independent assortment. Karl Wilhelm von Nägeli (1817-1891) Eric von Tcshermak的貢獻被忽略了! For lecture only; BC Yang

22. 我曾經在Tübingen Correns C 用的材料Matthiola incana 紫羅蘭 Correns 待過的植物園 For lecture only; BC Yang

23. 由種子商購買 34 個豌豆品種，培育兩年成為純系。他發現有22 株系的性狀穩定，然後又選定 7 種性狀作為觀察性狀在世代間傳遞情況的指標....... • 豌豆有七條染色體。 • 據說研究進行八年，對兩萬八千株植物進行交配實驗。這八年孟德爾在想什麼 ? • 在費曼之前 – 二十世紀的科學簡史; 陳恒安譯, 究竟, 台北 (2002), p 70. For lecture only; BC Yang

24. 在接受且理解孟德爾發現的必要條件有哪些? • 孟德爾以概念 (以 Elementet 稱呼他所追蹤的遺傳單位) 和假設的理論掌握自然的規律(關係) 。但是概念必須有實物相對應，才能展現其存在的意義。 For lecture only; BC Yang

25. 1866, Mendel published his lecture, a work that was to establish him as “the father of genetics”. • 1869 Johann Friedrich Miescher (nuclein) • 1873 Anton Schneider (meiosis) • 1879 Walther Flemming (chromaton, mitosis) • 1888 Wilhelm von Waldeyer-Hartz, (term chromosome) • 1902 Walter Stanborough Sutton. (chromosomes carry the units of inheritance) • 1904 Theodor Boveri (correlation between Mendel's factors and chromosomes ) • 1904 William Bateson (genetics) • 1909 Wilhelm Johannasen (gene)

26. DNA to chromosome to DNA • 1869Johann Friedrich Miescher identifies a weakly acidic substance of unknown function in the nuclei of human white blood cells. This substance will later be called deoxyribonucleic acid, or DNA. • 1924 Microscope studies using stains for DNA and protein show that both substances are present in chromosomes. • 1928Franklin Griffith, a British medical officer, discovers that genetic information can be transferred from heat-killed bacteria cells to live ones. This phenomenon, called transformation, provides the first evidence that the genetic material is a heat-stable chemical. • 1944Oswald Avery, Maclyn McCarty, and Colin MacLeod, identify Griffith's transforming agent as DNA. Good & simple reference to read: http://www.csuchico.edu/anth/CASP/Carmosino_P.html

27. It was while working on pus cells at Tübingen in 1869 that Miescher made his fundamental discovery. It was thought that such cells were made largely of protein, but Miescher noted the presence of something that "cannot belong among any of the protein substances known hitherto." • He showed that the new substance was derived from the nucleus of the cell alone and consequently named it 'nuclein'. • Miescher was soon able to show that nuclein could be obtained from many other cells and was unusual in containing phosphorus in addition to the usual ingredients of organic molecules - carbon, oxygen, nitrogen, and hydrogen. It was not until 1871 that Miescher's paper, delayed by Hoppe-Seyler (who wanted to confirm the results), was published. Miescher, Johann Friedrich II1844-1895 Switzerlander http://www.laskerfoundation.org/news/gnn/timeline/1869a.html For lecture only; BC Yang

28. 1873 and after • The discovery of chromosomes cannot be pinpointed to a single person. It was a consequence of the growing interest in the division processes of the fertilized egg. • Scientists on cell division : Anton Schneider, Eduard Strasburger, Otto Bütschli, Edouard van Beneden, Leopold Auerbach, Hermann Fol, Walther Flemming. For lecture only; BC Yang

29. Walther Flemming1843 - 1905 • 1879: he described and named "chromaton", "mitosis" and "spireme", made the first accurate counts of chromosome numbers and figured the longitudinal splitting of chromosomes. http://www.nature.com/cgi-taf/DynaPage.taf?file=/nrm/journal/v2/n1/full/nrm0101_072a_r.html For lecture only; BC Yang

30. Flemming observed for the first time that the chromosomes during cell division became split along their longitudinal axis, now known to consist of chromatids, and in 1880 he formulated the sentence: "Omnis nucleus e nucleo". • All nuclei come from nuclei (1863), omnis cellula e cellula

31. Walter Stanborough Sutton. • He was the U.S. geneticist (and also surgeon) who provided the first conclusive evidence that chromosomes carry the units of inheritance and occur in distinct pairs. • The two papers (Sutton, 1902, 1903) written as a graduate student under E. B. Wilson at Columbia University formulated the concept that chromosomes carried the units of heredity and explained Mendel's laws. 1877-1916 http://www.kumc.edu/research/medicine/anatomy/sutton/surgical_career.html http://post.queensu.ca/~forsdyke/guyer.htm#Chromosomes%20in%20Heredity For lecture only; BC Yang

32. I believe this is what Sutton has seen during his study at Columbia University (BC, 2004) • While he was working as a graduate student at Columbia University, studying grasshopper cells, Sutton observed that chromosomes occurred in distinct pairs, and that during meiosis, the chromosome pairs split, and each chromosome goes to its own cell. Sutton announced this discovery in his 1902 paper On the Morphology of the Chromosome Group in Brachyotola. http://www.kumc.edu/research/medicine/anatomy/sutton/surgical_career.html For lecture only; BC Yang

33. Theodor Boveri (1862-1915) • He saw that as egg cells matured, there comes a point where chromosome numbers are reduced in half. Boveri was one of the first to see evidence of the process of meiosis. (In the late 1880's and early 1890's) • When Mendel's laws were rediscovered in 1900, Boveri recognized the correlation between Mendel's factors and the cytology work being done on chromosomes (1904?). Some one had already improved the staining technique for chromosomes http://www.dnaftb.org/dnaftb/concept_8/con8bio.html For lecture only; BC Yang

34. Theodor Boveri, making use of the ideas from Carl Rabl put forward the hypothesis of the constancy of the amount of chromosomes and of their continuity during the Interphase stages of the nucleus (1887-1888). In 1904 Boveri already even thought it might be possible that the pairing of chromosomes would result in an exchange of genetic substance. 來源資料待查 Bamburg, Deutshland For lecture only; BC Yang

35. William Bateson (1861-1926) William Bateson describes gene linkage, showing that more than one gene may be required for a particular characteristic or trait (1904). A hereditary factor like, for example, the shape of the seed, the colour of the cotyledons or the colour of the seed shell shall be called a gene (following a suggestion of BATESON made in 1905). http://post.queensu.ca/~forsdyke/bateson1.htm For lecture only; BC Yang

36. http://www.dnaftb.org/dnaftb/concept_5/con5gallery.html First page of a 1905 letter written by William Bateson, first Director of the John Innes Institute, to Adam Sedgewick, Cambridge professor. Bateson coined the term "genetics" in this letter. he felt the need for a new term to describe the study of heredity and inherited variations. But the term didn’t start spreading until Wilhelm Johannsen suggested that the Mendelian factors of inheritance be called genes. For lecture only; BC Yang

37. Wilhelm Johannasen 1857-1927 • Danish botanist Wilhelm Johannsen coined the word gene (1909) to describe the Mendelian units of heredity. • He also made the distinction between the outward appearance of an individual (phenotype) and its genetic traits (genotype). • The proposed word traced from the Greek word genos, meaning "birth". The word spawned others, like genome. http://www.genome.gov/Pages/Education/Kit/main.cfm?pageid=24 For lecture only; BC Yang