Your search keyword '"Igor Minia"' showing total 3 results

1. Despite the odds: formation of the SARS-CoV-2 methylation complex

Author

Alex Matsuda, Jacek Plewka, Yuliya Chykunova, Alisha N. Jones, Magdalena Pachota, Michał Rawski, André Mourão, Abdulkarim Karim, Leanid Kresik, Kinga Lis, Igor Minia, Kinga Hartman, Ravi Sonani, Grzegorz Dubin, Michael Sattler, Piotr Suder, Paweł Mak, Grzegorz M. Popowicz, Krzysztof Pyrć, and Anna Czarna

Abstract

Coronaviruses protect their single-stranded RNA genome with a methylated cap during replication. The capping process is initiated by several nonstructural proteins (nsp) encoded in the viral genome. The methylation is performed by two methyltransferases, nsp14 and nsp16 where nsp10 acts as a co-factor to both. Aditionally, nsp14 carries an exonuclease domain, which operates in the proofreading system during RNA replication of the viral genome. Both nsp14 and nsp16 were reported to independently bind nsp10, but the available structural information suggests that the concomitant interaction between these three proteins should be impossible due to steric clashes. Here, we show that nsp14, nsp10, and nsp16 can form a heterotrimer complex. This interaction is expected to encourage formation of mature capped viral mRNA, modulating the nsp14’s exonuclease activity, and protecting the viral RNA. Our findings show that nsp14 is amenable to allosteric regulation and may serve as a novel target for therapeutic approaches.

Published

2022

2. The suppressive cap-binding-complex factor 4EIP is required for normal differentiation

Author

Elisha Mugo, Dorothea Droll, Franziska Egler, Igor Minia, Christine Clayton, Monica Terrao, Kevin Kamanyi Marucha, and Johanna Braun

Subjects

Messenger RNA, chemistry.chemical_compound, Cap binding complex, biology, Mrna level, chemistry, In vivo, EIF4G, Midgut, Trypanosoma brucei, biology.organism_classification, Cell biology

Abstract

Summary/AbstractTrypanosoma brucei live in mammals as bloodstream forms and in the Tsetse midgut as procyclic forms. Differentiation from one form to the other proceeds via a growth-arrested stumpy form with low mRNA content and translation. The parasites have six eIF4Es and five eIF4Gs. EIF4E1 pairs with the mRNA-binding protein 4EIP but not with any EIF4G. EIF4E1 and 4EIP each inhibit expression when tethered to a reporter mRNA. The 4E-binding motif in 4EIP is required for the interaction with EIF4E1 both in vivo and in a 2-hybrid assay, but not for the suppressive activity of 4EIP when tethered. However, the suppressive activity of EIF4E1 when tethered requires 4EIP. Correspondingly, in growing bloodstream forms, 4EIP is preferentially associated with unstable mRNAs. Trypanosomes lacking 4EIP have a marginal growth disadvantage as cultured bloodstream or procyclic forms. Bloodstream forms without 4EIP cannot make differentiation-competent stumpy forms, but the defect can be complemented by a truncated 4EIP that does not interact with EIF4E1. Bloodstream forms lacking EIF4E1 have a growth defect but can differentiate. We suggest that 4EIP and EIF4E1 fine-tune mRNA levels in growing cells, and that 4EIP is required for mRNA suppression during differentiation to the stumpy form.

Published

2018

3. Gene expression changes after heat shock of procyclic-form Trypanosoma brucei suggest that stress has a role in differentiation to mammalian-infective forms

Author

Igor Minia, Monica Terrao, Clementine Merce, and Christine Clayton

Subjects

Stress granule, Biochemistry, biology, Ribosomal protein, Polysome, Translational regulation, Gene expression, Granule (cell biology), P-bodies, Trypanosoma brucei, biology.organism_classification

Abstract

Trypanosome procyclic forms multiply in the midgut of Tsetse flies, and are routinely cultured at 27°C. Heat shocks of 37°C and above result in general inhibition of translation, and severe heat shock (41°C) results in sequestration of mRNA in granules. The mRNAs that are bound by the zinc-finger protein ZC3H11, including those encoding refolding chaperones, escape heat-induced translation inhibition.a At 27°C, ZC3H11 mRNA is predominantly present as an untranslated cytosolic messenger ribonucleoprotein particle, but after heat shocks of 37°C - 41°C, the ZC3H11 mRNA moves into the polysomal fraction. To investigate the scope and specificities of heat-shock translational regulation and granule formation, we analysed the distributions of mRNAs on polysomes at 27C and after 1 hour at 39°C, and the mRNA content of 41°C heat shocks granules. We found that that mRNAs that bind to ZC3H11 remained in polysomes at 39°C and were protected from sequestration in granules at 41°C. As previously seen for starvation stress granules, the mRNAs that encode ribosomal proteins were excluded from heat-shock granules. Seventy mRNAs moved towards the polysomal fraction after the 39°C heat shock; surprisingly, many of these are also increased when trypanosomes migrate to the Tsetse salivary glands. It therefore seems possible that in the wild, temperature changes due to diurnal variations and periodic intake of warm blood might influence the efficiency with which procyclic forms develop into mammalian-infective formsAuthor summaryWhen trypanosomes are inside tsetse flies, they have to cope with temperature variations from below 20°C up to nearly 40°C, due to diurnal variations and periodic intake of warm blood. The procyclic forms, which usually multiply in the midgut, are routinely cultured at 27°C in the laboratory. When they are heated to temperatures of 37°C and above, they shut down protein production, and at 41°C, mRNAs aggregate into granules. We show here that quite a large number of mRNAs are not included in granules and continue to be used for making proteins. Some of the proteins that continue to be made are needed in order to defend the cells against the effects of heat shock. Interestingly, however, a moderate heat shock stimulates expression of genes needed for the parasites to develop further into forms that can colonise the salivary glands. It thus seems possible that in the field, temperature variations might influence the efficiency with which of trypanosomes in tsetse flies become infective for mammals.

Published

2016