使用Nanodrop ND-1000的分光光度仪测定DNA
Spectrophotometric evaluation of DNA using a Nanodrop ND-1000. Spectrophotometric evaluation of genomic DNA quality and quantity using a microvolumetric Nanodrop ND-1000 optical fibre UV-Vis spectrophotometer.
Immunoblot analysis Sean Gallagher(UVP,LLC)and Deb Chakravart(Proteomic Center)
Immunoblot analysis Sean Gallagher(UVP,LLC)and Deb Chakravart(Proteomic Center)
克氏锥虫和Chagas病 - Norma andrews P1
本视频由科普中国和生物医学大讲堂出品
Norma andrews (U. Maryland) Part 1: Trypanosoma cruzi and Chagas’ Disease
Lecture overview:
Trypanosoma cruzi and Leishmania are closely related intracellular protozoan parasites that cause serious diseases throughout the world. In the first part of this lecture, I will present background material on the biology of Trypanosoma cruzi and the history of its discovery as an important agent of human disease in Latin America. I will also discuss the main characteristics of the disease, and the current efforts to stop human transmission.
In the second part of this lecture, I will present background material on Leishmania, the intracellular protozoan parasites responsible for severe human pathology in several parts of the world. I will discuss the main disease forms, the history of identification of the causative agent and form of transmission, and recent discoveries that established important concepts in our understanding of this increasingly serious infectious disease.
In the third part of this lecture, I will discuss current work from our laboratory on mechanisms used by the intracellular parasites Trypanosoma cruzi and Leishmania to interact with mammalian cells. In addition to clarifying specific molecular strategies used by these parasites to infect and survive within host cells, these studies also led, in some instances, to unexpected insights on novel pathways regulating mammalian cell function.
Speaker bio:
Norma andrews is currently a Professor and Chair of the Department of Cell Biology and Molecular Genetics at the University of Maryland. She received a B.S. degree in biology (1977) and a Ph.D. degree in biochemistry (1983) from the University of São Paulo, Brazil.
In 1990, after completing postdoctoral studies in the laboratory of Victor Nussenzweig at New York University, she was appointed Assistant Professor at Yale University where she remained until 2010.
andrews was a Burroughs Wellcome New Investigator, a Burroughs Wellcome Molecular Parasitology Scholar and recipient of a NIH MERIT Award. Her laboratory has made numerous contributions to the cell biology of host-pathogen interactions, and discoveries in this area have led to the identification and functional characterization of a novel pathway of Ca2+-regulated lysosomal exocytosis in mammalian cells.
利什曼原虫和利什曼病 - Norma andrews P2
本视频由科普中国和生物医学大讲堂出品
Norma andrews (U. Maryland) Part 2: Leishmania spp and Leishmaniasis
In the second part of this lecture, I will present background material on Leishmania, the intracellular protozoan parasites responsible for severe human pathology in several parts of the world. I will discuss the main disease forms, the history of identification of the causative agent and form of transmission, and recent discoveries that established important concepts in our understanding of this increasingly serious infectious disease.
Norma andrews moved from Yale University to the University of Maryland in 2010.
入侵细胞和在细胞内生存的策略 - Norma andrews P3
本视频由科普中国和生物医学大讲堂出品
Norma andrews (U. Maryland) Part 3: Strategies for Cell Invasion and Intracellular Survival
In the third part of this lecture, I will discuss current work from our laboratory on mechanisms used by the intracellular parasites Trypanosoma cruzi and Leishmania to interact with mammalian cells. In addition to clarifying specific molecular strategies used by these parasites to infect and survive within host cells, these studies also led, in some instances, to unexpected insights on novel pathways regulating mammalian cell function.
Norma andrews moved from Yale University to the University of Maryland in 2010.
头足纲动物的伪装和信号 - Roger Hanlon P1
本视频由科普中国和生物医学大讲堂出品
Roger Hanlon (MBL) Part 1: Camouflage and Signaling in Cephalopods
Hanlon introduces the amazing adaptive coloration of cephalopods. He uses video and still photography to showcase their ability to rapidly change color, pattern and skin texture with fine control and a diversity of appearances, to produce camouflage or to send signals. He argues that all camouflage patterns in nature can be grouped into three types. In part 2, Hanlon shows us results from his lab that make a convincing case that the rapid adaptive coloration of cephalopods is controlled by their visual system; quite impressive for a color-blind animal! Part 3 focuses on the unique skin of cephalopods including the system of pigments and reflectors that allows it to quickly change to any hue and contrast, and the papillae musculature that allows the skin to deform and create multiple 3D textures.
对头足纲动物视觉感知机制的探索 - Roger Hanlon P2
本视频由科普中国和生物医学大讲堂出品
Roger Hanlon (MBL) Part 2: Exploring Mechanisms of Visual Perception
Hanlon introduces the amazing adaptive coloration of cephalopods. He uses video and still photography to showcase their ability to rapidly change color, pattern and skin texture with fine control and a diversity of appearances, to produce camouflage or to send signals. He argues that all camouflage patterns in nature can be grouped into three types. In part 2, Hanlon shows us results from his lab that make a convincing case that the rapid adaptive coloration of cephalopods is controlled by their visual system; quite impressive for a color-blind animal! Part 3 focuses on the unique skin of cephalopods including the system of pigments and reflectors that allows it to quickly change to any hue and contrast, and the papillae musculature that allows the skin to deform and create multiple 3D textures.
头足纲动物的可变化的皮肤细胞 - Roger Hanlon P3
本视频由科普中国和生物医学大讲堂出品
Roger Hanlon (MBL) Part 3: Changeable Skin
Hanlon introduces the amazing adaptive coloration of cephalopods. He uses video and still photography to showcase their ability to rapidly change color, pattern and skin texture with fine control and a diversity of appearances, to produce camouflage or to send signals. He argues that all camouflage patterns in nature can be grouped into three types. In part 2, Hanlon shows us results from his lab that make a convincing case that the rapid adaptive coloration of cephalopods is controlled by their visual system; quite impressive for a color-blind animal! Part 3 focuses on the unique skin of cephalopods including the system of pigments and reflectors that allows it to quickly change to any hue and contrast, and the papillae musculature that allows the skin to deform and create multiple 3D textures.
免疫反应的细胞基础 - Ira Mellman P1
本视频由科普中国和生物医学大讲堂出品
Ira Mellman (Genentech) Part 1: Cellular Basis of the Immune Response
The immune system is charged with protecting us from invading microorganisms, a task that falls to a complex array of highly specialized cell types spread throughout the body but that must work together as an integrated system. How they accomplish and perform their functions can be wonderfully understood by probing the basic mechanisms governing their activities. In the first video, we will consider the overall organization of the immune response in cellular terms, the innate immune system (comprising evolutionarily ancient phagocytic cells that recognize conserved molecules of microorganisms) and the adaptive immune system (composed of lymphocytes that recognize chemically diverse antigens).