Denes Kovacs

Chaperone Activity of ERD10 and ERD14, Two Disordered Stress-Related Plant Proteins

ERD10 and ERD14 (for early response to dehydration) proteins are members of the dehydrin family that accumulate in response to abiotic environmental stresses, such as high salinity, drought, and low temperature, in Arabidopsis (Arabidopsis thaliana). Whereas these proteins protect cells against the consequences of dehydration, the exact mode(s) of their action remains poorly understood. Here, detailed evidence is provided that ERD10 and ERD14 belong to the family of intrinsically disordered proteins, and it is shown in various assays that they act as chaperones in vitro. ERD10 and ERD14 are able to prevent the heat-induced aggregation and/or inactivation of various substrates, such as lysozyme, alcohol dehydrogenase, firefly luciferase, and citrate synthase. It is also demonstrated that ERD10 and ERD14 bind to acidic phospholipid vesicles without significantly affecting membrane fluidity. Membrane binding is strongly influenced by ionic strength. Our results show that these intrinsically disordered proteins have chaperone activity of rather wide substrate specificity and that they interact with phospholipid vesicles through electrostatic forces. We suggest that these findings provide the rationale for the mechanism of how these proteins avert the adverse effects of dehydration stresses.

Intrinsically disordered chaperones in plants and animals.

Intrinsically disordered proteins (IDPs) are widespread in eukaryotes and fulfill important functions associated with signaling and regulation. Recent evidence points to a special and thus largely disrespected functional capacity of IDPs--that they can assist the folding of other proteins and prevent their aggregation, i.e., that they can act as chaperones. In this paper, we survey current information available on this phenomenon, with particular focus on (i) the structure and function of IDPs in general, (ii) disordered chaperones in plants, (iii) disordered chaperones in other organisms spanning from insects to mammals, (iv) the possible mechanisms of action of disordered chaperones, and (v) the possibility of two-faced (Janus) chaperone activity of disordered chaperones, which can assist the folding of both RNA and protein substrates. The evidence is most conclusive in the case of plant stress proteins, such as late embryogenesis abundant (LEA) proteins or dehydrins. We will show that the cellular function of LEA proteins in mitigating the damage caused by stress is clear; nevertheless, experiments carried out in vivo must be extended and the molecular mechanism of the action of IDP chaperones also requires clarification. Using these details, we chart out how far the field has progressed only to emphasize the long road ahead before chaperone function can be firmly established as part of the physiological mechanistic arsenal of the emerging group of IDPs.

Disordered plant LEA proteins as molecular chaperones

Plants often respond to abiotic stresses by the increased expression of LEA (late embryogenesis abundant) proteins, so called because they also accompany seed formation. Whereas the cellular function of LEA proteins in mitigating the damage caused by stress is clear, the molecular mechanisms of their action are rather enigmatic. Several models have been developed, based on their putative activities as ion sinks, stabilizers of membrane structure, buffers of hydrate water, antioxidants, and/or chaperones. Due to their known structural flexibility, this latter idea has received little experimental attention thus far. Recently, however, it has been suggested that intrinsically disordered proteins (IDPs) may exert chaperone activity by an “entropy transfer” mechanism. In our subsequent study published in the May issue of Plant Physiology, we provided evidence that two group 2 LEA proteins, ERD (early response to dehydration) 10 and 14, are potent molecular chaperones. This observation may have far-reaching implications, as it may explain how LEA proteins of ill-defined structures protect plant cells during dehydration, and it may also lead to the general experimental validation of the entropy transfer model of disordered chaperones. Addendum to: Kovacs D, Kalmar E, Torok Z, Tompa P. Chaperone activity of ERD10 and ERD14, two disordered stress-related plant proteins. Plant Physiol. 2008; 147: 381–390.

Local structural preferences of calpastatin, the intrinsically unstructured protein inhibitor of calpain

Calpain, the calcium-activated intracellular cysteine protease, is under the tight control of its intrinsically unstructured inhibitor, calpastatin. Understanding how potent inhibition by calpastatin can be reconciled with its unstructured nature provides deeper insight into calpain function and a more general understanding of how proteins devoid of a well-defined structure carry out their function. To this end, we performed a full NMR assignment of hCSD1 to characterize it in its solution state. Secondary chemical shift values and NMR relaxation data, R 1, R 2, and hetero-NOE, as well as spectral density function analysis have shown that conserved regions of calpastatin, subdomains A and C, which are responsible for calcium-dependent anchoring of the inhibitor to the enzyme, preferentially sample partially helical backbone conformations of a reduced flexibility. Moreover, the linker regions between subdomains are more flexible with no structural preference. The primary determinant of calpain inhibition, subdomain B, also has a non-fully random conformational preference, resembling a beta-turn structure also ascertained by prior studies of a 27-residue peptide encompassing the inhibitory region. This local structural preference is also confirmed by a deviation in chemical shift values between full-length calpastatin domain 1 and a truncated construct cut in the middle of subdomain B. At the C-terminal end of the molecule, a nascent helical region was found, which in contrast to the overall structural properties of the molecule may indicate a previously unknown functional region. Overall, these observations provide further evidence that supports previous suggestions that intrinsically unstructured proteins use preformed structural elements in efficient partner recognition.

Full backbone assignment and dynamics of the intrinsically disordered dehydrin ERD14

Dehydrins are a class of stress proteins that belong to the family of Late Embryogenesis Abundant (LEA) proteins in plants, so named because they are highly expressed in late stages of seed formation. In somatic cells, their expression is very low under normal conditions, but increases critically upon dehydration elicited by water stress, high salinity or cold. Dehydrins are thought to be intrinsically disordered proteins, which represents a challenge in understanding their structure–function relationship. Herein we present the backbone 1H, 15N and 13C NMR assignment of the 185 amino acid long ERD14 (Early Response to Dehydration 14), which is a K3S-type, typical dehydrin of A. thaliana. Secondary chemical shifts as well as NMR relaxation data show that ERD14 is fully disordered under near native conditions, with short regions of somewhat restricted motion and 5–25% helical propensity. These results suggest that ERD14 may have partially preformed elements for functional interaction with its partner(s) and set the stage for further detailed structural and functional studies of ERD14 both in vitro and in vivo.

Calcium-induced tripartite binding of intrinsically disordered calpastatin to its cognate enzyme, calpain

MINT‐6549073: Calpain-2 catalytic subunit (uniprotkb:P04632), Calpain-2 catalytic subunit (uniprotkb:P17655) and calpastatin (uniprotkb:P20810) physically interact (MI:0218) by nuclear magnetic resonance (MI:0077)

Diverse functional manifestations of intrinsic structural disorder in molecular chaperones

IDPs (intrinsically disordered proteins) represent a unique class of proteins which show diverse molecular mechanisms in key biological functions. The aim of the present mini-review is to summarize IDP chaperones that have increasingly been studied in the last few years, by focusing on the role of intrinsic disorder in their molecular mechanism. Disordered regions in both globular and disordered chaperones are often involved directly in chaperone action, either by modulating activity or through direct involvement in substrate identification and binding. They might also be responsible for the subcellular localization of the protein. In outlining the state of the art, we survey known IDP chaperones discussing the following points: (i) globular chaperones that have an experimentally proven functional disordered region(s), (ii) chaperones that are completely disordered along their entire length, and (iii) the possible mechanisms of action of disordered chaperones. Through all of these details, we chart out how far the field has progressed, only to emphasize the long road ahead before the chaperone function can be firmly established as part of the physiological mechanistic arsenal of the emerging group of IDPs.

Ensemble Methods Enable a New Definition for the Solution to Gas-Phase Transfer of Intrinsically Disordered Proteins

Intrinsically disordered proteins (IDPs) are important for health and disease, yet their lack of net structure precludes an understanding of their function using classical methods. Gas-phase techniques provide a promising alternative to access information on the structure and dynamics of IDPs, but the fidelity to which these methods reflect the solution conformations of these proteins has been difficult to ascertain. Here we use state of the art ensemble techniques to investigate the solution to gas-phase transfer of a range of different IDPs. We show that IDPs undergo a vast conformational space expansion in the absence of solvent to sample a conformational space 3-5 fold broader than in solution. Moreover, we show that this process is coupled to the electrospray ionization process, which brings about the generation of additional subpopulations for these proteins not observed in solution due to competing effects on protein charge and shape. Ensemble methods have permitted a new definition of the solution to gas-phase transfer of IDPs and provide a roadmap for future investigations into flexible systems by mass spectrometry.

A novel method for assessing the chaperone activity of proteins

Protein chaperones are molecular machines which function both during homeostasis and stress conditions in all living organisms. Depending on their specific function, molecular chaperones are involved in a plethora of cellular processes by playing key roles in nascent protein chain folding, transport and quality control. Among stress protein families–molecules expressed during adverse conditions, infection, and diseases–chaperones are highly abundant. Their molecular functions range from stabilizing stress-susceptible molecules and membranes to assisting the refolding of stress-damaged proteins, thereby acting as protective barriers against cellular damage. Here we propose a novel technique to test and measure the capability for protective activity of known and putative chaperones in a semi-high throughput manner on a plate reader. The current state of the art does not allow the in vitro measurements of chaperone activity in a highly parallel manner with high accuracy or high reproducibility, thus we believe that the method we report will be of significant benefit in this direction. The use of this method may lead to a considerable increase in the number of experimentally verified proteins with such functions, and may also allow the dissection of their molecular mechanism for a better understanding of their function.

The androgen receptor gene polyglycine repeat polymorphism is associated with memory performance in healthy Chinese individuals.

Cognitive functions such as memory are quantitative traits in human, and have both genetic and environmental influences. Testosterone has been implicated in the modulation of memory function. Therefore, genetic variation which influences testosterone signaling may modulate memory function. The principal receptor for testosterone is the androgen receptor, the gene for which maps to the X chromosome. In the present study, we hypothesized that common variation in two functional polymorphisms in the androgen receptor gene, the polyglutamine (CAG) and/or polyglycine (GGN) repeats, would influence memory function in healthy subjects. Variation in length of either repeat modulates the function of the AR gene, either by changing the amount of protein produced, by altering transactivation of the receptor or by producing toxic polyglycine or polyglutamine fragments. In order to test this hypothesis, we analyzed 449 healthy Chinese individuals. CAG repeats were not associated with memory performance. However we observed a significant association between GGN repeats and Immediate Logical Memory (chi(2)=23.6, d.f.=7, p=0.001) and Delayed Logical Memory (chi(2)=16.3, d.f.=7, p=0.022). The association of GGN repeats with Immediate Logical Memory remained significant after 6000 permutation corrections (p=0.013). There was also a sex difference, as association between GGN repeats and memory was observed only in females (p=0.002 for Immediate and p=0.014 for Delayed Logical Memory), but not in males (p=0.31 and 0.83, respectively). We conclude that functional variation of the androgen receptor gene is able to modulate memory function in women.