Michał Tracz scite author profile

Protein ubiquitination has become one of the most extensively studied post-translational modifications. Originally discovered as a critical element in highly regulated proteolysis, ubiquitination is now regarded as essential for many other cellular processes. This results from the unique features of ubiquitin (Ub) and its ability to form various homo- and heterotypic linkage types involving one of the seven different lysine residues or the free amino group located at its N-terminus. While K48- and K63-linked chains are broadly covered in the literature, the other types of chains assembled through K6, K11, K27, K29, and K33 residues deserve equal attention in the light of the latest discoveries. Here, we provide a concise summary of recent advances in the field of these poorly understood Ub linkages and their possible roles in vivo.

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E3 Ubiquitin Ligase SPL2 Is a Lanthanide-Binding Protein

Tracz

Górniak

Szczepaniak

et al. 2021

IJMS

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The SPL2 protein is an E3 ubiquitin ligase of unknown function. It is one of only three types of E3 ligases found in the outer membrane of plant chloroplasts. In this study, we show that the cytosolic fragment of SPL2 binds lanthanide ions, as evidenced by fluorescence measurements and circular dichroism spectroscopy. We also report that SPL2 undergoes conformational changes upon binding of both Ca2+ and La3+, as evidenced by its partial unfolding. However, these structural rearrangements do not interfere with SPL2 enzymatic activity, as the protein retains its ability to auto-ubiquitinate in vitro. The possible applications of lanthanide-based probes to identify protein interactions in vivo are also discussed. Taken together, the results of this study reveal that the SPL2 protein contains a lanthanide-binding site, showing for the first time that at least some E3 ubiquitin ligases are also capable of binding lanthanide ions.

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Insights into the Structure of Rubisco from Dinoflagellates-In Silico Studies

Rydzy

Tracz

Szczepaniak

et al. 2021

IJMS

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Ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) is one of the best studied enzymes. It is crucial for photosynthesis, and thus for all of biosphere’s productivity. There are four isoforms of this enzyme, differing by amino acid sequence composition and quaternary structure. However, there is still a group of organisms, dinoflagellates, single-cell eukaryotes, that are confirmed to possess Rubisco, but no successful purification of the enzyme of such origin, and hence a generation of a crystal structure was reported to date. Here, we are using in silico tools to generate the possible structure of Rubisco from a dinoflagellate representative, Symbiodinium sp. We selected two templates: Rubisco from Rhodospirillum rubrum and Rhodopseudomonas palustris. Both enzymes are the so-called form II Rubiscos, but the first is exclusively a homodimer, while the second one forms homo-hexamers. Obtained models show no differences in amino acids crucial for Rubisco activity. The variation was found at two closely located inserts in the C-terminal domain, of which one extends a helix and the other forms a loop. These inserts most probably do not play a direct role in the enzyme’s activity, but may be responsible for interaction with an unknown protein partner, possibly a regulator or a chaperone. Analysis of the possible oligomerization interface indicated that Symbiodinium sp. Rubisco most likely forms a trimer of homodimers, not just a homodimer. This hypothesis was empowered by calculation of binding energies. Additionally, we found that the protein of study is significantly richer in cysteine residues, which may be the cause for its activity loss shortly after cell lysis. Furthermore, we evaluated the influence of the loop insert, identified exclusively in the Symbiodinium sp. protein, on the functionality of the recombinantly expressed R. rubrum Rubisco. All these findings shed new light onto dinoflagellate Rubisco and may help in future obtainment of a native, active enzyme.

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Białka chaperonowe zaangażowane w biosyntezę Rubisco.

Rydzy

Tracz

Kolesinski³

et al. 2021

Postepy Biochem

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Rubisco jest enzymem występującym u organizmów fotosyntetyzujących katalizującym pierwszy etap procesu akumulacji biomasy, przyłączenie dwutlenku węgla do cukru, rybulozo-1,5-bisfosforanu. Skomplikowana, multimeryczna budowa i obecność wielu labilnych elementów strukturalnych w tym białku, powodują że nie jest ono w stanie samodzielnie uzyskać swojej natywnej struktury czwartorzędowej i wymaga do tego celu ściśle zorganizowanego działania szeregu czynników pomocniczych. Wyspecjalizowane białka chaperonowe uczestniczą kolejno w fałdowaniu podjednostek holoenzymu, pośredniczą w ich stopniowej oligomeryzacji, a w niektórych przypadkach dodatkowo kierują do komórkowego miejsca przeznaczenia, takiego jak karboksysomy, czy pyrenoid. Oprócz pełnienia swojej kanonicznej funkcji, polegającej na pośredniczeniu w składaniu Rubisco, chaperony te zaangażowane są w dodatkowe procesy, takie jak kontrola jakości procesu biosyntezy, czy regulacja fizjologii organelli i kompartmentów komórkowych.

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Michał Tracz

Beyond K48 and K63: non-canonical protein ubiquitination

E3 Ubiquitin Ligase SPL2 Is a Lanthanide-Binding Protein

Insights into the Structure of Rubisco from Dinoflagellates-In Silico Studies

Białka chaperonowe zaangażowane w biosyntezę Rubisco.

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