about
Changes in antibody avidity after virus infections: detection by an immunosorbent assay in which a mild protein-denaturing agent is employedMouse anti-benzylpenicilloyl IgE monoclonal antibody: preparation, characterization and cross-reactivitySticky egyptians: a technique for assembling genes encoding constrained peptides of variable lengthIdentification of mutant monoclonal antibodies with increased antigen bindingSomatic diversification of the S107 (T15) VH11 germ-line gene that encodes the heavy-chain variable region of antibodies to double-stranded DNA in (NZB x NZW)F1 miceStructural correlates of high antibody affinity: three engineered amino acid substitutions can increase the affinity of an anti-p-azophenylarsonate antibody 200-foldStepwise intraclonal maturation of antibody affinity through somatic hypermutationProtein evolution on partially correlated landscapes.The extent of affinity maturation differs between the memory and antibody-forming cell compartments in the primary immune response.Surface plasmon resonance measurements of plasma antibody avidity during primary and secondary responses to anthrax protective antigen.Protein carriers of conjugate vaccines: characteristics, development, and clinical trials.Regulation of immunoglobulin transcription rates and mRNA processing in proliferating normal B lymphocytes by activators of protein kinase CQualitative and quantitative aspects of the human antibody response to streptococcal group A carbohydrate.Early preservation of CXCR5+ PD-1+ helper T cells and B cell activation predict the breadth of neutralizing antibody responses in chronic HIV-1 infection.Kinetic and affinity limits on antibodies produced during immune responses.Contact regions for dinitrophenyl and menadione haptens in an immunoglobulin binding more than one antigen.Specific fractionation of immune cell populations.Antibodies with multiple binding functions. Induction of single immunoglobin species by structurally dissimilar haptens.Differences in potential for amino acid change after mutation reveals distinct strategies for kappa and lambda light-chain variationAdjuvants and myeloid-derived suppressor cells: enemies or allies in therapeutic cancer vaccination.The induction of hapten-specific immunological tolerance and immunity in B lymphocytes. VI. Differential tolerance susceptibility in adult spleen as a function of B-cell maturation level.High affinity germinal center B cells are actively selected into the plasma cell compartment.Different epitope structures select distinct mutant forms of an antibody variable region for expression during the immune response.In vitro-initiated secondary anti-hapten response. II. Increasing cell avidity for antigen.Induction and reversal of immune paralysis in vitro.Antigen-specific cells in mouse bone marrow. II. Fluctuation of the number and potential of immunocyte precursors after immunization.Cellular receptors. effect of anti-alloantiserum on the recognition of transplantation antigens.Receptors on immunocompetent cells. 3. Specificity and nature of receptors on dinitrophenylated guinea pig albumin- 125 I-binding cells of immunized guinea pigsImmune responses in vitro. IV. Suppression of primary M, G, and A plaque-forming cell responses in mouse spleen cell cultures by class-specific antibody to mouse immunoglobulinsImmune responses in vitro. V. Suppression of M, G, and A plaque-forming cell responses in cultures of primed mouse spleen cells by class-specific antibody to mouse immunoglobulins.The immune response against hapten-autologous protein conjugates in the mouseGenetic control of the antibody response to type 3 pneumococcal polysaccharide in mice. I. Evidence that an X-linked gene plays a decisive role in determining responsiveness.Immunological maturation. Preferential proliferation of high-affinity precursor cells.Binding of antigen by immunocytes. I. Effect of ligand valence on binding affinity of MOPC 315 cells for DNP conjugates.Isolation of antigen-binding cells from unprimed mice: demonstration of antibody-forming cell precursor activity and correlation between precursor and secreted antibody avidities.Ontogeny of B-lymphocyte function. I. Restricted heterogeneity of the antibody response of B lymphocytes from neonatal and fetal mice.Specific cellular stimulation in the primary immune response: a quantized modelInhibition of T-antigen-binding cells by idiotypic antisera.Complete inhibition of the expression of an idiotype by a mechanism of B-cell dominanceImmunoregulatory circuits that modulate responsiveness to suppressor cell signal. Failure of B10 mice to respond to suppressor factors can be overcome by quenching the contrasuppressor circuit.
P2860
Q27488943-C3A9A36D-A5C1-4C1E-AC3D-FBE7971F914CQ28361911-CE0ED4CD-BBC1-4FDA-A274-9FBE6E3DEE6EQ32063458-D30A8071-BF36-4838-A2A8-229F65CC5E13Q33564356-2A6EFA20-3673-4094-99D0-6F84E6F39D04Q33578476-8B111381-05B9-4322-A8C4-1F1C9E7E3600Q33646218-F95A0A03-6415-4A71-A38C-62C82DF3FE9EQ33664973-B7487626-E19B-4CBB-8294-31895D41BD52Q33860729-1A68BEC3-5756-4616-83B0-96AB783750DFQ33886727-557965D4-CD5D-454F-8426-1857C31F7C66Q33922778-BD6D7E03-27C2-4D2D-B1CB-CD994B42E81DQ34170021-61D79E58-B6ED-43EE-9B9B-63E5D61EBE94Q34379927-9FC0F481-71F9-49F2-BA92-AB1F33F0C33AQ34468577-E129D5A6-67B9-441A-AFBD-32E4D442D45EQ34594726-F046C486-6BE7-48DE-A654-928C4E53CB92Q34598643-37A07E80-28BB-4DEB-ADC3-886030EC2F7BQ34699135-E5432C84-A6E4-427F-B738-E61FB5C569EEQ34711429-49E4AAB3-F2F3-46A3-BF59-E4BA8DE07403Q34743638-1FCDA1DA-8EC1-47DB-8709-80CAD3C43385Q35127575-38812DFA-9351-48D2-AABF-FAA9E1753F6CQ35886450-F9C2A4B7-2466-44C2-9504-1110EE904966Q36086962-063D86D6-F223-4C16-AFCE-F7EAF99DB0A0Q36228042-F468EF59-CD43-44D9-B3BB-87B9F5CA8608Q36229997-DE9C32DA-60F1-45F1-A3B3-49014244C6F4Q36270503-01551859-62E4-40D2-806E-8E8E5905ABB9Q36270541-FE81E8AC-A954-4B62-952E-3D74FADE853AQ36270710-8CF17030-A128-48C4-BEFC-5AC15AB1112DQ36271069-176218DC-DD56-4063-B161-A5A81022A92FQ36271198-C367A5DA-37D6-4ED3-9595-0310342E0A89Q36271483-6FE3AF0F-41BC-4626-9366-8A99AC4C6A67Q36271486-07ED9002-6FE7-4B97-918B-302C44F2E94FQ36271789-D7998C3D-103D-49CA-B9F9-82B2EB648EDDQ36271994-BC2027AE-CA35-4981-AF17-8EF598758096Q36272313-776F537C-ACB7-4AFA-B41E-6A077BF7914CQ36272769-B7A4A362-AC13-4AB5-B4C3-F85A2090F710Q36273318-0B1C90A5-E576-4453-9B42-38D7A1E3E5C9Q36273625-8FB5EDA8-4B02-44F1-8F39-E7F710A40849Q36277172-6F2F956E-9D35-47D9-A9BD-2FB34E49042DQ36335822-D97DA54E-7FCE-4054-A316-7FDF8C15E52CQ36337229-8250E418-09B8-4492-A36E-07539099A4B2Q36344823-AAC01A28-7DCA-4B36-8957-5456D558B27A
P2860
description
1969 nî lūn-bûn
@nan
1969年の論文
@ja
1969年学术文章
@wuu
1969年学术文章
@zh-cn
1969年学术文章
@zh-hans
1969年学术文章
@zh-my
1969年学术文章
@zh-sg
1969年學術文章
@yue
1969年學術文章
@zh
1969年學術文章
@zh-hant
name
Cell selection by antigen in the immune response.
@en
Cell selection by antigen in the immune response.
@nl
type
label
Cell selection by antigen in the immune response.
@en
Cell selection by antigen in the immune response.
@nl
prefLabel
Cell selection by antigen in the immune response.
@en
Cell selection by antigen in the immune response.
@nl
P1476
Cell selection by antigen in the immune response
@en
P2093
Benacerraf B
Siskind GW
P577
1969-01-01T00:00:00Z