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010   $a1-68108-128-8
035   $a(CKB)3710000000531584
035   $a(EBL)4412590
035   $a(MiAaPQ)EBC4412590
035   $a(EXLCZ)993710000000531584
100   $a20160614d2015      uy|            0
101 0 $aeng
135   $aur|n|---|||||
181   $2rdacontent
182   $2rdamedia
183   $2rdacarrier
200 00$aFlagellar mechanics and sperm guidance /$f[editor], Jacky J. Cosson, University of South Bohemia in Ceske Budejovice, Faculty of Fisheries and Protection of Waters CENAKVA, Czech Republic
210  1$aSharjah :$cBentham Science Publishers, Limited,$d[2015]
215   $a1 online resource (457 p.)
300   $aDescription based upon print version of record.
311   $a1-68108-129-6 
320   $aIncludes bibliographical references and index.
327   $aCONTENTS; FOREWORD ; ACKNOWLEDGEMENTS ; DEDICATION ; List of Contributors ; ABOUT THE AUTHORS ; The Flagellar Mechanics of Spermatozoa and its Regulation ; INTRODUCTION; 1. STRUCTURE, BIOCHEMICAL COMPOSITION AND BUILDING OF AN AXONEME; 1-1. Structure; 1-2. Biochemical Composition; 1-3. The Structural and Biochemical Complexity of the Flagellar Axoneme; 1-4. The Building of an Axoneme; 2. BIOPHYSICAL PARAMETERS OF BEATING FLAGELLA THAT GOVERN SPERM MOTILITY; 3. OPERATION OF A FLAGELLAR MICROMOTOR; 3-1. Cilia and Flagella Use Similar Elements for Their Functioning; 3-2. Notion of Sliding
327   $a3-3. Bending Engendered by the Sliding3-4. Regulation Responsible of Alternative Movement; 3-5. Enzymological and Structural Data on the Flagellar Micro-Motor; 3-6. Need for a Resistance to Sliding; 4. OPERATIONAL MODELS; 4-1. Presentation of the Main Models; 4-2. Wave Propagation; 4-2-1. Curvature-controlled Model; 4-2-2. Sliding-controlled Switching Model; 4-3. Predictions on the Mechanism for Regulation of Waves and Its Consequences; 5. INTERNAL VERSUS EXTERNAL REGULATION OF AXONEMAL ACTIVITY ; 5-1. Internal Regulation; 5-2. Regulatory Complexes in the Axoneme; 5-3. External Regulation
327   $a5-4. Initiation of Flagella Activity: Biochemical Aspects5-5. Mechanisms Underlying Motility Maturation and Activation Events; 5-6. Initiation of Flagella Activity: Phenomenological Aspects; 6. ENERGETIC ASPECTS; 6-1. Source and use of Energy: Biochemical Aspects; 6-2. Force, Power and Energy in the Flagellum: Mechanical Aspects; 7. EVOLUTIONARY CONSIDERATIONS ON THE AXONEMAL ORGANELLE AND ON THE SPERM GUIDANCE MECHANISMS; 8. CONCLUSIONS ABOUT SPERM MOTILITY AND ITS ACTIVATION; CONFLICT OF INTEREST; ACKNOWLEDGEMENTS; NOTIFICATION; REFERENCES; Sea Urchin Sperm Chemotaxis ; 1. INTRODUCTION
327   $a2. GAMETE COMMUNICATION, SENSING OF SPATIAL CUES2.1. Sperm-Activating Peptides and the Taxonomy of Echinoids; 2.2. SAP Receptors and the Membrane-Associated Guanylate Cyclase; 2.3. Gradient Detection Constraints; 3. SIGNALING; 4. CA2+ SIGNALS AND FLAGELLAR DYNAMICS; 5. CURRENT EFFORTS OF MODELING TO UNDERSTAND CHEMOTAXIS; 5.1. Modeling Focused on Signaling; 5.2. Modelling Focused on Sperm Chemotactic Movement; 5.3. Efforts for Comprehensive Modelling; PERSPECTIVES; CONFLICT OF INTEREST; ACKNOWLEDGEMENTS; REFERENCES; Sperm Chemotaxis in Urochordates ; INTRODUCTION
327   $aFEATURES OF ASCIDIAN SPERM CHEMOTAXISSPECIFICITY OF ASCIDIAN SPERM CHEMOTAXIS; SIGNALING OF SPERM CHEMOTAXIS; Sperm Attractants; Receptor of Sperm Attractants; Species Specificity of Sperm Chemotaxis Revisited: Discussion on the Molecular Basis of Specificity; Sperm Attractants Induce Ca2+ Bursts in the Spermatozoa; CONTROL OF SPERM FLAGELLAR MOVEMENT DURING CHEMOTAXIS; [Ca2+]i Controls Sperm Flagellar Movement; Molecular Components of the Axonemes in Ascidian Sperm; Calaxin is a Ca2+-sensor Protein of Outer Arm Dynein
327   $aCalaxin Drives Sperm Chemotaxis by Propagating Flagellar Asymmetric Waveform
606   $aSpermatozoa
606   $aSpermatogensis
608   $aElectronic books.
615  0$aSpermatozoa.
615  0$aSpermatogensis.
702   $aCosson$b Jacky J.
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910493174303321
996   $aFlagellar mechanics and sperm guidance$92487826
997   $aUNINA