Port Weller Dry Docks collection, 1959-1967

Port Weller Dry Docks Limited was officially established on April 25, 1946, near Lock 1 of the Welland Canal. Charles A. Ansell was the company’s first President and General Manager. Initially, the company focused on repairing ships, but in June, 1951, built their first ship, the Scott Misener. In 1956, the Upper Lakes and St. Lawrence Transportation Co. purchased all of the shares of Port Weller Dry Docks Limited. In the mid-eighties, ULS (Upper Lakes Shipping) International (which owned the Port Weller dry docks), and Canada Steamship Lines, merged their operations. As a result, the Port Weller Dry Docks became a division of this newly formed company, known as Canadian Shipbuilding and Engineering Limited. In 2007, Seaway Marine & Industrial Inc. took over ownership of the Port Weller Dry Docks, but declared bankruptcy in July 2013.

Post Card Album - Welland Canal

A collection of post cards (52 black & white and 47 colour) and photographs (26 black & white) of the Welland Canal. The photographs and post cards cover a range of years and locations, inlcuding St. Catharines, Port Colborne, Port Dalhousie; Humberstone, Thorold, Allanburg and Niagara Falls.

Welland Industry - Postcards

Board of five postcards of Welland. First postcard, Welland Riverside Mills. Second postcard, Plymouth Cordage Co., Welland, Ont. Third postcard, Ship Yard, Welland Canal, Welland, Ont. Fourth postcard, Welland Cordage Co., Fifth postcard, Cordage St.., Welland, Ont.

Upper Lakes Shipping Ltd. Vessels Scrapbook, 1964-1967, no date

The origins of Upper Lakes Shipping can be traced back to 1931, when Gordon Leitch, the general manager of Toronto elevators, sent Captain Bruce Angus to scout for potential ships that could be used to transport grain. The ship Sarnian was purchased as a result. It soon became apparent that more ships would be needed by the business, and Leitch subsequently partnered with James Norris of the Norris Grain Company, in order to transport their products more economically. The Upper Lakes and St. Lawrence Transportation Company (which later become known as Upper Lakes Shipping), was incorporated in 1932. In 1956, the company bought Port Weller Dry docks. At this point, the company began constructing new vessels designed to meet specific freight and classification needs.

Schooner Ranger document, 1810-1815

Partial transcription: Buffalo, August 15, 1815 This day settled all accounts between… respecting the purchase and sailing of the Schooner Ranger until she was laid up in the fare of 1811. For the value of the…of the said Schooner destroyed by the enemy in January 1813 and the rigging & c taken by the U.S. Navy Officers for the use of the Government a [Joint][appreciation] is to be made... Government for our mutual benefit. Porter & Barton for [the firm] of Porter Barton & Co. George Kibbe

Letter - E.C. Schmon to Arthur A. Schmon, 11 & 12 September 1918

Eleanore Celeste describes Arthur's departure for service one year ago. She also discusses a friend, Dick Hart, who was thought to have been a casualty of a torpedoed ship, but is now thought to be safe. She mentions that she will visit Mother Schmon and had played tennis with Gus. The letter is labelled number 159.

Letter - E.C. Schmon to Arthur A. Schmon, 20 December 1919

Eleanore Celeste discusses the ice breaker ship that travels to Quebec. Arthur has asked if the boat will travel the first trip soon and she responds that she is not sure if it will make the trip, but will wait until the New Year to find out more. She mentions that Arthur is going to buy her a fur for her Christmas gift. The letters are labelled number 78 & 79.

Persia steamboat poster, no date

The “Persia” was built in St. Catharines in 1873. From 1877 to 1894 the ship was owned by James Norris of St. Catharines. The Toronto and Montreal Steamboat Co. acquired the ship in 1894, followed by the Quebec Navigation Co. in 1907. A fire severely damaged the ship in 1911, and the following year the “Persia” was rebuilt as a barge.

Photograph - House Interior, Dining Room

Black and white photographs, 19 cm x 24 cm of the interior of an unidentified house showing a dining room with a model ship on the table. The photograph was taken by Wurts Brothers General Photographers of New York City (2 copies).

Letter - Howard Helliwell to S.D. Woodruff

Letter with letterhead “Sylvester Neelon, Vessel and Steamboat Owner, Merchant Miller and Manufacturer of Ship Timber” addressed to S.D. Woodruff regarding the pew at St. George’s Church. “This pew which was owned by Howard Helliwell is now at your disposal and the rent is paid up to Oct. 1st”, Oct. 2, 1886

Niagara Falls Handbill Collection, 1838-1886, n.d. (non-inclusive)

According to legend, the Burning Springs were discovered by early natives in the Niagara Peninsula. Bridgewater Mills was built on the site of the spring. During the excavation of the factory; workmen uncovered the spring. Samuel Street and Thomas Clark recognized the potential of this as a tourist attraction so they built a wooden shelter over the spring. The spring was covered with a barrel with a pipe protruding from it. This became the first tourist attraction at Niagara. The Cave of the Winds was a cavern located behind the Bridal Veil Fall. It was originally named the Aeolus Cave. In 1920, a sudden rock fall from the ceiling killed 3 tourists. The cave was destroyed in 1955 as it was deemed dangerous. The captain of the Maid of the Mist was usually a farmer who owned the land where the ship docked. In 1846, the first steam powered Maid of the Mist was launched. By 1848, the first suspension bridge was built over the gorge and the main purpose of the Maid of the Mist was no longer to carry people who needed to travel, but now the focus was on people who wanted to view the Falls at close range. Source: http://www.niagarafrontier.com/burningsprings.html http://www.niagarafrontier.com/winds.html http://reservationsystems.com/niagara_daredevils/maid_of_the_mist.html

Commodore Hull Medallion, Poem and Presidential Messages

1 cardboard clam shell case with a bronze medallion in a front portal. The medallion is 6 cm. in circumference with a bust of Commodore Isaac Hull on the face. The medallion was designed by John Reich. A translation of the words inscribed on the front is: “Isaac Hull conquers in July 1812, the skilled by stratagem and in August, the strong in battle” On the back is a ship and the words “Horae Momento Victoria” which translate to “Victory in the space of an hour”. The title on the front of the box has the words “War of 1812, Jonathan Russell, Commodore Hull”. Only 126 of these medallions were estimated to be struck. Also within this collection is a poem written by Jonathan Russell and 2 messages from President James Madison.

La légitimité de l'État du port de contrôler la navigabilité des navires

"Mémoire présenté à la Faculté des études supérieures En vue de l'obtention du grade de maître en droit Option droit des affaires"

La chaîne de responsabilité de la sécurité maritime

"Mémoire présenté à la faculté des études supérieures en vue de l'obtention du grade de maître en droit (LL.M.)". Ce mémoire a été accepté à l'unanimité et classé parmi les 15% des mémoires de la discipline.

Caractérisation moléculaire de la modulation spatio-temporelle des fonctions du phagosome

La phagocytose est un processus par lequel des cellules spécialisées du système immunitaire comme les macrophages ingèrent des microorganismes envahisseurs afin de les détruire. Les microbes phagocytés se retrouvent dans un compartiment intracellulaire nommé le phagosome, qui acquiert graduellement de nombreuses molécules lui permettant de se transformer en phagolysosome possédant la capacité de tuer et dégrader son contenu. L’utilisation de la protéomique a permis de mettre en évidence la présence de microdomaines (aussi nommés radeaux lipidiques ou radeaux membranaires) sur les phagosomes des macrophages. Notre équipe a démontré que ces radeaux exercent des fonctions cruciales au niveau de la membrane du phagosome. D’abord nous avons observé que la survie du parasite intracellulaire L. donovani est possible dans un phagosome dépourvu de radeaux lipidiques. Parallèlement nous avons constaté qu’un mutant de L. donovani n’exprimant pas de LPG à sa surface(LPG-) est rapidement tué dans un phagosome arborant des radeaux membranaires. Pour comprendre le mécanisme de perturbation des microdomaines du phagosome par la molécule LPG, nous avons provoqué la phagocytose de mutants LPG- du parasite et comparé par microscopie les différences avec le parasite de type sauvage. Nous avons ainsi démontré que le LPG de L. donovani est nécessaire et suffisant au parasite pour empêcher la maturation normale du phagosome. Nous avons également découvert que la molécule LPG permet d’empêcher la formation des radeaux lipidiques sur le phagosome et peut aussi désorganiser les radeaux lipidiques préexistants. Enfin, nous avons montré que l’action de LPG est proportionnelle au nombre d’unités répétitives de sucres (Gal(β1,4)-Manα1-PO4) qui composent cette molécule. Nos travaux ont démontré pour la première fois le rôle important de ces sous-domaines membranaires dans la maturation du phagosome. De plus, nos conclusions seront des pistes à suivre au cours des études cliniques ayant pour but d’enrayer la leishmaniose. Le second objectif de ce travail consistait à effectuer la caractérisation des radeaux lipidiques par une analyse protéomique et lipidomique à l’aide de la spectrométrie de masse. Nous avons ainsi entrepris l’identification systématique des protéines présentes dans les radeaux membranaires des phagosomes et ce, à trois moments clés de leurmaturation. Le traitement des phagosomes purifiés avec un détergent nous a permis d’isoler les «Detergent Resistent Membranes» (DRMs) des phagosomes, qui sont l’équivalent biochimique des radeaux membranaires. Nous avons ainsi établi une liste de 921 protéines associées au phagosome, dont 352 sont présentes dans les DRMs. Les protéines du phagosome sont partagées presque également entre trois tendances cinétiques (augmentation, diminution et présence transitoire). Cependant, une analyse plus spécifique des protéines des DRMs démontre qu’une majorité d’entre elles augmentent en fonction de la maturation. Cette observation ainsi que certains de nos résultats montrent que les radeaux lipidiques des phagosomes précoces sont soit très peu nombreux, soit pauvres en protéines, et qu’ils sont recrutés au cours de la maturation du phagosome. Nous avons aussi analysé les phospholipides du phagosome et constaté que la proportion entre chaque classe varie lors de la maturation. De plus, en regardant spécifiquement les différentes espèces de phospholipides nous avons constaté que ce ne sont pas uniquement les espèces majoritaires de la cellule qui dominent la composition de la membrane du phagosome. L’ensemble de nos résultats a permis de mettre en évidence plusieurs fonctions potentielles des radeaux lipidiques, lesquelles sont essentielles à la biogenèse des phagolysosomes (signalisation, fusion membranaire, action microbicide, transport transmembranaire, remodelage de l’actine). De plus, la cinétique d’acquisition des protéines de radeaux lipidiques indique que ceux-ci exerceraient leurs fonctions principalement au niveau des phagosomes ayant atteint un certain niveau de maturation. L’augmentation du nombre de protéines des radeaux membranaires qui s’effectue durant la maturation du phagosome s’accompagne d’une modulation des phospholipides, ce qui laisse penser que les radeaux membranaires se forment graduellement sur le phagosome et que ce ne sont pas seulement les protéines qui sont importées.