The Principles of Biology sequence (BI 211, 212 and 213) introduces biology as a scientific discipline for students planning to major in biology and other science disciplines. Laboratories and classroom activities introduce techniques used to study biological processes and provide opportunities for students to develop their ability to conduct research.
Cilia and Flagella presents protocols accessible to all individuals working with eukaryotic cilia and flagella. These recipes delineate laboratory methods and reagents, as well as critical steps and pitfalls of the procedures. The volume covers the roles of cilia and flagella in cell assembly and motility, the cell cycle, cell-cell recognition and other sensory functions, as well as human diseases and disorders. Students, researchers, professors, and clinicians should find the book's combination of "classic" and innovative techniques essential to the study of cilia and flagella.Key Features* A complete guide containing more than 80 concise technical chapters friendly to both the novice and experienced researcher* Covers protocols for cilia and flagella across systems and species from Chlamydomonas and Euglena to mammals* Both classic and state-of-the-art methods readily adaptable across model systems, and designed to last the test of time, including microscopy, electrophoresis, and PCR* Relevant to clinicians interested in respiratory disease, male infertility, and other syndromes, who need to learn biochemical, molecular, and genetic approaches to studying cilia, flagella, and related structures
The Biology of Cilia and Flagella reviews advances in the study of cilia and flagella since 1928. This book focuses on four main topics—structure of cilia, factors that affect ciliary activity, movement of cilia and flagella, and coordination of beat of cilia. In these topics, this compilation specifically discusses the intracellular structures associated with ciliary bases; viscosity of the medium and ciliary activity, and energy relationships of cilia and flagella. The compounding of synchronously beating cilia, variations in shaft structure, and control of ciliary activity by the organism are also elaborated. This text likewise covers the determination of the rate of beat of cilia and root-fiber systems and coordination of ciliary beat. This publication is suitable for biologists and clinicians of other disciplines researching on the structure and physiology of cilia and flagella.
Motility is an inherent property of living organisms, both unicellular and multicellular. One of the principal mechanisms of cell motility is the use of peculiar biological engines - flagella and cilia. These types of movers already appear in prokaryotic cells. However, despite the similar function, bacteria flagellum and eukaryote flagella have fundamentally different structures. Chapter One of this book by Drs. Meijiao Wang, Li Zhang and Hanna Li is devoted to a comparative analysis of the flagella of prokaryotes and eukaryotes.It's believed that flagellum in eukaryotic cells appeared for the first time in ancient flagellates. In Chapter Two, Drs. P. Huitorel, M. Cachon and J. Cosson summarize the results of their long-term studies of flagellum dinoflagellates. The "evolutionary invention" of the ancient flagellates proved to be so successful that the axonemal structure in flagellum has not changed for hundreds of millions of years. In the third chapter, Drs. V. Bondarenko, G. Prokopchuk and J. Cosson reported the analyses of kinetic characteristics of flagella motions in fish using the most modern methodologies.In Chapter Four, Drs. R. Uzbekov, A. Garanina, J. Burlaud-Gaillard and C. Bressac described spermiogenesis of the parasitic wasps Cotesia congregata. Their data showed that significant shortening of the flagella occurs during the formation of the mature spermatozoon and this flagella has been the shortest spermatozoon flagella described in the animal kingdom until now. Centriole in this spermatozoon is transformed into a special structure known as the "cogwheel structure" that does not contain microtubules.In the process of multicellular organism evolution, flagella, which ensure the mobility of individual cells, gave origin to two types of cilia. Motile cilia in the tissues like cerebral ventricles, respiratory epithelium and oviducts moved liquid flows relatively to immobile cell layers. The second type of cilia (primary cilia) lost motility function and acquired cellular sensitivity function. Moving and sensitive cilia grow from basal bodies, which originate from centrioles. Chapter Five by Drs. I. Alieva, C. Staub, S. Uzbekova and R. Uzbekov discusses which of the centrioles - mother or daughter - creates the moving cilium and sensitive cilium.In Chapter Six, Drs. D. Conkar and E. Nur Firat-Karalar describe in detail the biochemical aspects of primary cilium assembly pathways, intraflagellar transport and ectosome release. This chapter provides an overview of the trafficking pathways involved in ciliary compartmentalization and describes the primary ciliary as a sensitive "cell's antenna", participating in many regulatory processes in the cell.Defects in flagella and cilia cause many hereditary diseases. Different examples of ciliopathy are described in Chapter Seven by Drs. E. Bragina, E. Blanchard and R. Uzbekov.A wide review of experimental models, organisms and analytical methods to study flagella and cilia are presented to readers who want to learn about their main research directives.
In recent years, the role of cilia in the study of health, development and disease has been increasingly clear, and new discoveries have made this an exciting and important field of research. This comprehensive volume, a complement to the new three-volume treatment of cilia and flagella by King and Pazour, presents easy-to-follow protocols and detailed background information for researchers working with cilia and flagella. - Covers protocols for primary cilia across several systems and species - Both classic and state-of-the-art methods readily adaptable across model systems, and designed to last the test of time - Relevant to clinicians and scientists working in a wide range of fields
Genes and Evolution, the latest volume in the Current Topics in Developmental Biology series, covers genes and evolution, with contributions from an international board of authors. The chapters provide a comprehensive set of reviews covering such topics as genes and plant domestication, gene networks, phenotypic loss in vertebrates, reproducible evolutionary changes, and epithelial tissue. - Covers the area of genes and evolution - Contains invaluable contributions from an international board of authors - Provides a comprehensive set of reviews covering such topics as genes and plant domestication, gene networks, phenotypic loss in vertebrates, reproducible evolutionary changes and epithelial tissue
Integrated Nano-Biomechanics provides an integrated look into the rapidly evolving field of nanobiomechanics. The book demystifies the processes in living organisms at the micro- and nano-scale through mechanics, using theoretical, computational and experimental means. The book develops the concept of integrating different technologies along the hierarchical structure of biological systems and clarifies biomechanical interactions among different levels for the analysis of multi-scale pathophysiological phenomena. With a focus on nano-scale processes and biomedical applications, it is shown how knowledge obtained can be utilized in a range of areas, including diagnosis and treatment of various human diseases and alternative energy production. This book is based on collaboration of researchers from a unique combination of fields, including biomechanics, computational mechanics, GPU application, electron microscopy, biology of motile micro-organisms, entomological mechanics and clinical medicine. The book will be of great interest to scientists and researchers involved in disciplines, such as micro- and nano-engineering, bionanotechnology, biomedical engineering, micro- and nano-scale fluid-mechanics (such as in MEMS devices), nanomedicine and microbiology, as well as industries such as optical devices, computer simulation, plant based energy sources and clinical diagnosis of the gastric diseases. - Provides knowledge of integrated biomechanics, focusing on nano-scale, in this rapidly growing research field - Explains how the different technologies can be integrated and applied in a variety of biomedical application fields, as well as for alternative energy sources - Uses a collaborative, multidisciplinary approach to provide a comprehensive coverage of nano-biomechanics
Nearly every cell in the human body has one or more protrusive structures called cilia or flagella. These power cell movement and fluid flow, sense the extracellular environment, coordinate cell signaling, and establish left-right asymmetry during development. Mutations in genes that encode cilia can lead to disorders known as ciliopathies. Written and edited by experts in the field, this collection from Cold Spring Harbor Perspectives in Biology examines key aspects of ciliary biology-from the molecular to the organismal level-in normal physiology and disease. The contributors dissect the complex structures of motile and nonmotile (primary) cilia, discuss how the intraflagellar transport machinery moves cargo across the central axoneme, and review how the ciliary gate controls the composition of cilia and flagella. The roles of cilia in coordinating cellular responses to environmental stimuli via cell signaling pathways (e.g., Hedgehog) are also covered, as are physiological functions in processes such as fertilization, mucociliary clearance, and vision. The authors also survey the wide spectrum of ciliopathies, describing their genetic bases, pathogenic mechanisms, and clinical manifestations. This volume is therefore an indispensable reference for all cell and developmental biologists, as well as medical geneticists and clinical scientists wishing to understand and treat disorders involving ciliary dysfunction.
This book vividly describes how complex and integrated movements can arise from the properties and behaviors of biological molecules. It provides a uniquely integrated account in which the latest findings from biophysics and molecular biology are put into the context of living cells. This second edition is updated throughout with recent advances in the field and has a completely revised and redrawn art program. The text is suitable for advanced undergraduates, graduate students, and for professionals wishing for an overview of this field.