about
Was a change in thermohaline circulation responsible for the Little Ice Age?Functional analysis of the rat N-methyl-D-aspartate receptor 2A promoter: multiple transcription starts points, positive regulation by Sp factors, and translational regulationPalaeoceanography: motivations and challenges for the future.Abrupt climate change in the computer: is it real?The role of the thermohaline circulation in abrupt climate change.Developmental stage differences in chromatin subdomains of the beta-globin locus.DNA supercoiling allows enhancer action over a large distancePromoter-proximal tethering elements regulate enhancer-promoter specificity in the Drosophila Antennapedia complex.Genome-wide identification of tissue-specific enhancers in the Ciona tadpole.The Holocene temperature conundrum.Ocean circulation and climate during the past 120,000 years.The 5'-HS4 chicken beta-globin insulator is a CTCF-dependent nuclear matrix-associated elementAndrogen-induced recruitment of RNA polymerase II to a nuclear receptor-p160 coactivator complex.T cell receptor (TCR) alpha/delta locus enhancer identity and position are critical for the assembly of TCR delta and alpha variable region genes.Long-range enhancer-promoter interactions in the Scr-Antp interval of the Drosophila Antennapedia complex.From the Cover: Antarctic climate signature in the Greenland ice core record.Replacement of Igamma3 germ-line promoter by Igamma1 inhibits class-switch recombination to IgG3.Imprecise probability assessment of tipping points in the climate system.North Atlantic warming during Dansgaard-Oeschger events synchronous with Antarctic warming and out-of-phase with Greenland climate.Synchronicity of Antarctic temperatures and local solar insolation on orbital timescales.Context-dependent GATA factor function: combinatorial requirements for transcriptional control in hematopoietic and endothelial cells.A T cell-specific enhancer of the human CD40 ligand gene.Transient simulation of last deglaciation with a new mechanism for Bolling-Allerod warming.Boron isotope evidence for oceanic carbon dioxide leakage during the last deglaciation.The role of intron sequences in high level expression from CD45 cDNA constructs.Strong hemispheric coupling of glacial climate through freshwater discharge and ocean circulation.Regulation of forestomach-specific expression of the murine adenosine deaminase gene.Lack of enhancer function in mammals is unique to oocytes and fertilized eggs.Temporal regulation of enhancer function in intestinal epithelium: a role for Onecut factors.Polycomb complexes and the propagation of the methylation mark at the Drosophila ubx gene.Earth science: An extended yardstick for climate variability.Synthesis of the Nature and Causes of Rapid Climate Transitions During the QuaternaryAtlantic ocean heat piracy and the bipolar climate see-saw during Heinrich and Dansgaard-Oeschger eventsOn the limits of Antarctic and marine climate records synchronization: Lag estimates during marine isotopic stages 5d and 5cA late medieval warm period in the Southern Ocean as a delayed response to external forcing?A new 27 ky high resolution East Antarctic climate recordA minimum thermodynamic model for the bipolar seesawRelative impacts of insolation changes, meltwater fluxes and ice sheets on African and Asian monsoons during the HoloceneObservations, inferences, and mechanisms of the Atlantic Meridional Overturning Circulation: A reviewModeling North American Freshwater Runoff through the Last Glacial Cycle
P2860
Q24610319-EA897EB6-2510-4465-B5D8-80A2A924188AQ28566552-E4E44A59-2A72-4AEE-8134-08F5A3D0C266Q30576328-A6ACD97A-BACC-479C-A6C8-1FD7BD8668C4Q30586795-42529D7F-4466-4619-A29B-59E5AA39B3ADQ30675841-E6900A58-00EB-4214-9A89-35B627DC89ADQ33782323-B400B6F0-4684-40EF-BBA0-4BF59BBBD272Q33952723-8A1215F3-0806-495C-A359-19D64BA1FBC9Q34034597-5A3854CB-967D-4D1B-B586-67121A3A78A7Q34067533-E5E4E631-C9E4-4371-9DE3-C53926F70660Q34120245-B64718E9-B80C-477E-AD55-0143EA4790FEQ34149223-75F1919F-EE49-4F9B-97E6-CF34EAD445F6Q34513920-CBC9B63A-3484-407F-BA01-677109A28D65Q34803985-5073DA74-8564-48D9-A798-EE6432AA4149Q34807453-3C07CC12-D28E-4DCE-BD1C-2F5BC4BB5D78Q35814205-592F68FB-FF73-41F1-949B-D72B32100D4EQ36141345-F3C160E6-2D8A-45D7-A758-1E571F8C8879Q36300042-3C58FCAB-B056-4D9A-985F-F2831279DB83Q37133185-35879DA8-1073-4B6A-B166-853CECD44FFFQ38265930-EF761FCA-7857-41E4-9483-944782AE4847Q39113504-B639CF51-D143-47E4-BE00-C134A3A4CFD2Q40161650-D3847108-3535-42EE-AC15-8590EE99E071Q40761786-C78E3579-1B8F-45B8-A0FE-C9B1CA620892Q41995144-7CBFA9E3-E9F3-4F4B-BD6B-38CF6FEF876DQ43528468-E150AFAC-A338-4005-81C1-749ED5C8DED3Q46645679-029B8657-141E-4253-AC46-BAFB760EFE36Q47306812-56D029DB-C440-4D8C-A8D0-B436EFDEBAB2Q47975127-687C8502-1854-420D-A057-704FBB1288F6Q48922549-6E6E8A55-73ED-4844-B9A7-2B4505FA27C8Q52007718-D4C7C1F5-09D1-4CA5-9085-B1A340DB403EQ52010804-BC9C49D2-AA9C-4101-B3EB-71A887B18883Q53742534-304C4DC0-C658-4DBB-B19C-D4F2B4260BF0Q56016683-A8492883-738F-4EFA-A382-AF5631F94F93Q56016889-887A9702-008B-4680-A6E7-984439651611Q56100542-105B2E96-B5A8-4198-BE75-DC838D911212Q56100582-2B06D247-B546-4DF7-842C-3077DFF8832DQ56100619-FCD13105-8CC4-470B-8EB1-4ED8ACEFC8F3Q56431763-E30EB082-FE37-4B1A-927F-8C2B05369300Q56527765-6F277FB6-E09F-4151-A5A0-88AF87AB0E4AQ56679219-C8BD9ED5-69BE-4C4F-A372-CC14349C0C2AQ56804402-C6868D46-DCCF-47A9-A3ED-CD95D9838077
P2860
description
wetenschappelijk artikel
@nl
наукова стаття, опублікована в жовтні 1998
@uk
name
CLIMATE CHANGE:The Seesaw Effect
@en
CLIMATE CHANGE:The Seesaw Effect
@nl
type
label
CLIMATE CHANGE:The Seesaw Effect
@en
CLIMATE CHANGE:The Seesaw Effect
@nl
prefLabel
CLIMATE CHANGE:The Seesaw Effect
@en
CLIMATE CHANGE:The Seesaw Effect
@nl
P1476
CLIMATE CHANGE:The Seesaw Effect
@en
P2093
T. F. Stocker
P356
10.1126/SCIENCE.282.5386.61
P577
1998-10-02T00:00:00Z