大规模风电场对草地碳循环的影响

Deployment of wind energy is an essential renewable energy source that mitigates climate change and reduces air pollution[1].Over the last several decades,wind energy development has increased worldwide,expanding from~20 to~900 GW(gigawatt)during 2001–2022[1].

Blockade of CD28 by a synthetical peptoid inhibits T-ce proliferation and attenuates graft-versus-host disease

CD28 is one of the costimulatory molecules crucial for T-cell activation and thus has become an attractive target for therapeutic immunomodulation. Conventional strategies for blocking CD28 activity using monoclonal antibodies, Fab fragments, antagonistic peptide and fusion proteins, have apparent disadvantages such as inherent immunogenicity, unwanted Fc signaling, poor tissue penetration and bioinstability. Recent research has been directed toward the creation of non-natural, sequence-specific biomimetic oligomers with bioinspired structures that capture the amino-acid interface of the targeted proteins. One such family of molecules is the poly-N-substituted glycines or peptoids, which have close structural similarity to peptides but are essentially invulnerable to protease degradation. To screen for peptoids that specifically target CD28, we first designed and chemically synthesized 19 candidate peptoids based on molecular modeling and docking. Using the phage-displaying system that expresses the extracellular domain of the CD28 homodimer and contains the core B7-binding motif, a peptoid （No. 9） with a molecular formula of C21H29N307, was identified to display the highest binding activity to CD28. This peptoid not only inhibited the lymphocyte proliferation in vitro, but suppressed immunoresponses against alloantigens in vivo, and attenuated the graft-versus-host disease in a mouse bone-marrow transplantation model. These results suggested that peptoids targeting CD28 are effective agents for blocking the CD28-mediated costimulation and suitable for development of novel therapeutic approaches for diseases involving this pathway.

Higher plant photosynthetic capability in autumn responding to low atmospheric vapor pressure deficit

It has been long established that the terrestrial vegetation in spring has stronger photosynthetic capability than in autumn.However,this study challenges this consensus by comparing photosynthetic capability of terrestrial vegetation between the spring and autumn seasons based on measurements of 100 in situ eddy covariance towers over global extratropical ecosystems.At the majority of these sites,photosynthetic capability,indicated by light use efficiency(LUE)and apparent quantum efficiency,is significantly higher in autumn than in spring,due to lower atmosphere vapor pressure deficit(VPD)at the same air temperature.Seasonal VPD differences also substantially explain the interannual variability of the differences in photosynthetic capability between spring and autumn.We further reveal that VPD in autumn is significantly lower than in spring over 74.14% of extratropical areas,based on a global climate dataset.In contrast,LUE derived from a data-driven vegetation production dataset is significantly higher in autumn in over 61.02% of extratropical vegetated areas.Six Earth system models consistently projected continuous larger VPD values in spring compared with autumn,which implies that the impacts on vegetation growth will long exist and should be adequately considered when assessing the seasonal responses of terrestrial ecosystems to future climate conditions.