Pushing, pulling and trapping--modes of motor protein supported protein translocation

Protein translocation across the cellular membranes is an ubiquitous and crucial activity of cells. This process is mediated by translocases that consist of a protein conducting channel and an associated motor protein. Motor proteins interact with protein substrates and utilize the free energy of ATP binding and hydrolysis for protein unfolding, translocation and unbinding. Since motor proteins are found either at the cis- or trans-side of the membrane, different mechanisms for translocation have been proposed. In the Power stroke model, cis-acting motors are thought to push, while trans-motors pull on the substrate protein during translocation. In the Brownian ratchet model, translocation occurs by diffusion of the unfolded polypeptide through the translocation pore while directionality is achieved by trapping and refolding. Recent insights in the structure and function of the molecular motors suggest that different mechanisms can be employed simultaneously.     

Hsc70-Auxilin复合物的拉伸分子动力学模拟

Hsc70与auxilin蛋白组成的系统是Hsp70/Hsp40分子伴侣系统家族的一员,在热休克反应中发挥重要作用。本文为得出auxilin蛋白J结构域的关键氨基酸,首先采用由二硫键交联的Hsc70 R171C与auxilin D876C的复合物结晶结构作为初始模型,进行分子动力学模拟,通过比较平衡后的结合部位发现,将形成二硫键的氨基酸突变为原来的氨基酸结构在结合位点上与生化结果较为相近,之后利用此结构通过拉伸动力学模拟分析了auxilin蛋白J结构域与Hsc70的ATPase功能域的解离过程,并探讨了Hsc70与auxilin蛋白之间的相互作用力。结果表明位于HPD loop上的His874,Asp876,Thr879,螺旋Ⅲ上的Glu884,Asn895,Asp896,Ser899,Glu902,Asn903为关键氨基酸,这些数据符合之前核磁共振实验证实的T抗原J结构域的HPD基序和螺旋Ⅲ与Hsc70的ATPase功能域之间的相互作用。     

Structural Basis of the Regulation of the CbpA Co-chaperone by its Specific Modulator CbpM

CbpA, one of the Escherichia coli DnaJ homologues, acts as a co-chaperone in the DnaK chaperone system. Despite its extensive similarity in domain structure and function to DnaJ, CbpA has a unique and specific regulatory mechanism mediated through the small protein CbpM. Both CbpA and CbpM are highly conserved in bacteria. Earlier studies showed that CbpM interacts with the N-terminal J-domain of CbpA inhibiting its co-chaperone activity but the structural basis of this interaction is not known. Here, we have combined NMR spectroscopy, site-directed mutagenesis and surface plasmon resonance to characterize the CbpA/CbpM interaction at the molecular level. We have determined the solution structure of the CbpA J-domain and mapped the residues that are perturbed upon CbpM binding. The NMR data defined a broad region on helices α2 and α3 as involved in the interactions. Site-directed mutagenesis has been used to further delineate the CbpA J-domain/CbpM interface. We show that the binding sites of CbpM and DnaK on CbpA J-domain overlap, which suggests a competition between DnaK and CbpM for binding to CbpA as a mechanism for CbpA regulation. This study also provides the explanation for the specificity of CbpM for CbpA versus DnaJ, by identifying the key residues for differential binding.     

J蛋白研究进展

J蛋白（J-domain protein）是一类分子中含有J结构域的蛋白质大家族,大部分J蛋白具有分子伴侣的功能。J蛋白作为热休克蛋白70（HSP70）的同伴蛋白与HSP70组成分子伴侣机器,参与蛋白质分子折叠、组装、转运以及信号转导等多种细胞过程。此外,J蛋白在植物对环境胁迫的反应及其他生理过程中起重要作用。     

The J-domain protein Rme-8 interacts with Hsc70 to control clathrin-dependent endocytosis in Drosophila

By screening for mutants exhibiting interactions with a dominant-negative dynamin, we have identified the Drosophila homologue of receptor-mediated endocytosis (Rme) 8, a J-domain-containing protein previously shown to be required for endocytosis in Caenorhabditis elegans. Analysis of Drosophila Rme-8 mutants showed that internalization of Bride of sevenless and the uptake of tracers were blocked. In addition, endosomal organization and the distribution of clathrin were greatly disrupted in Rme-8 cells, suggesting that Rme-8 participates in a clathrin-dependent process. The phenotypes of Rme-8 mutants bear a strong resemblance to those of Hsc70-4, suggesting that these two genes act in a common pathway. Indeed, biochemical and genetic data demonstrated that Rme-8 interacts specifically with Hsc70-4 via its J-domain. Thus, Rme-8 appears to function as an unexpected but critical cochaperone with Hsc70 in endocytosis. Because Hsc70 is known to act in clathrin uncoating along with auxilin, another J-protein, its interaction with Rme-8 indicates that Hsc70 can act with multiple cofactors, possibly explaining its pleiotropic effects on the endocytic pathway.     

拟南芥AtJ2和AtJ3基因表达对环境胁迫的响应

用PCR的方法获得AtJ2和AtJ3基因的3'非编码区的核甘酸片段作为探针,Northern杂交结果表明:AtJ2和AtJ3基因在植物的根、茎、叶、花蕾、花和长角果中都有表达,并在植物整个生长周期中都有表达,但随着植株的衰老表达量有所下降.不同环境胁迫的实验结果表明:热激使AtJ2和AtJ3基因的表达迅速升高;冷胁迫也能诱导这两个基因表达的明显增加,但需要的时间比热激要长得多,达9 h;水分胁迫能引起AtJ2和AtJ3基因表达量的微弱增加;可盐胁迫对AtJ2和AtJ3基因的表达没有影响.说明AtJ2和AtJ3基因可能参与对除盐胁迫以外多种环境刺激的响应.     

Two distinct classes of cochaperones compete for the EEVD motif in heat shock protein 70 to tune its chaperone activities

Chaperones of the heat shock protein 70 (Hsp70) family engage in protein–protein interactions with many cochaperones. One “hotspot” for cochaperone binding is the EEVD motif, found at the extreme C terminus of cytoplasmic Hsp70s. This motif is known to bind tetratricopeptide repeat domain cochaperones, such as the E3 ubiquitin ligase CHIP. In addition, the EEVD motif also interacts with a structurally distinct domain that is present in class B J-domain proteins, such as DnaJB4. These observations suggest that CHIP and DnaJB4 might compete for binding to Hsp70’s EEVD motif; however, the molecular determinants of such competition are not clear. Using a collection of EEVD-derived peptides, including mutations and truncations, we explored which residues are critical for binding to both CHIP and DnaJB4. These results revealed that some features, such as the C-terminal carboxylate, are important for both interactions. However, CHIP and DnaJB4 also had unique preferences, especially at the isoleucine position immediately adjacent to the EEVD. Finally, we show that competition between these cochaperones is important in vitro, as DnaJB4 limits the ubiquitination activity of the Hsp70–CHIP complex, whereas CHIP suppresses the client refolding activity of the Hsp70–DnaJB4 complex. Together, these data suggest that the EEVD motif has evolved to support diverse protein–protein interactions, such that competition between cochaperones may help guide whether Hsp70-bound proteins are folded or degraded.     

Crystallization and preliminary X-ray crystallographic properties of Hsc20, a J-motif co-chaperone protein from Escherichia coli.

Hsc20 is a 20-kDa auxiliary protein that functions with the molecular chaperone Hsc66 in Escherichia coli. Crystals of Hsc20 suitable for X-ray diffraction analysis were grown using the hanging drop vapor diffusion technique in polyethylene glycol 400 containing dioxane as an additive to slow growth. The crystals are monoclinic and belong to the space group C2 with unit cell dimensions a = 125.4 A, b = 71.9 A, c = 68.8 A, and beta = 97.0 degrees. The crystals diffract to a minimum d-spacing of approximately 2.5 A resolution, and a native data set was collected to 2.7 A. The results of a self-rotation function analysis revealed threefold symmetry, suggesting three molecules of Hsc20 in the asymmetric unit and, hence, 12 molecules in the unit cell; this corresponds to a Vm value of 2.6 A3/Da and a solvent content of approximately 53% in the crystals. Structure determination by isomorphous replacement is in progress.