Fernando Rodríguez-Castañeda scite author profile

Ca2+ signalling in neurons through calmodulin (CaM) has a prominent function in regulating synaptic vesicle trafficking, transport, and fusion. Importantly, Ca2+–CaM binds a conserved region in the priming proteins Munc13‐1 and ubMunc13‐2 and thus regulates synaptic neurotransmitter release in neurons in response to residual Ca2+ signals. We solved the structure of Ca2+4–CaM in complex with the CaM‐binding domain of Munc13‐1, which features a novel 1‐5‐8‐26 CaM‐binding motif with two separated mobile structural modules, each involving a CaM domain. Photoaffinity labelling data reveal the same modular architecture in the complex with the ubMunc13‐2 isoform. The N‐module can be dissociated with EGTA to form the half‐loaded Munc13/Ca2+2–CaM complex. The Ca2+ regulation of these Munc13 isoforms can therefore be explained by the modular nature of the Munc13/Ca2+–CaM interactions, where the C‐module provides a high‐affinity interaction activated at nanomolar [Ca2+]i, whereas the N‐module acts as a sensor at micromolar [Ca2+]i. This Ca2+/CaM‐binding mode of Munc13 likely constitutes a key molecular correlate of the characteristic Ca2+‐dependent modulation of short‐term synaptic plasticity.

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Structures of archaeal DNA segregation machinery reveal bacterial and eukaryotic linkages

Schumacher

Tonthat

Lee

et al. 2015

Science

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Although recent studies have provided a wealth of information about archaeal biology, nothing is known about the molecular basis of DNA segregation in these organisms. Here we unveil the machinery and assembly mechanism of the archaeal Sulfolobus pNOB8 partition system. This system employs three proteins; ParA, an atypical ParB adaptor and a centromere-binding component, AspA. AspA utilizes a spreading mechanism to create a DNA superhelix onto which ParB assembles. This supercomplex links to the ParA motor, which contains a bacteria-like Walker motif. The ParB C-domain harbors structural similarity to CenpA, which dictates eukaryotic segregation. Thus, this archaeal system combines bacteria-like and eukarya-like components, suggesting the possible conservation of DNA segregation principles across the three domains of life.

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Convenient Synthesis of Multifunctional EDTA‐Based Chiral Metal Chelates Substituted with an S‐Mesylcysteine

Leonov

Voigt

Rodríguez-Castañeda

et al. 2005

Chemistry A European J

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We describe the synthetic route to ethylenediaminetetraacetic acid (EDTA) derivatives that can be attached to surface-exposed thiol functional groups of cysteine residues in proteins, via a methylthiosulfonate moiety that is connected in a stereochemically unique way to the C-1 carbon atom of EDTA. Such compounds can be used to align proteins in solution without the need to add liquid crystalline media, and are, therefore, of great interest for the NMR spectroscopic analysis of biomolecules. The binding constant for the paramagnetic tag to lanthanide ions was determined by measuring luminescence. For the Tb(+3)-ligand complex, a K(b) value of 6.5 x 10(17) M(-1) was obtained. This value is in excellent agreement with literature values for the related EDTA compound. In addition, it could be shown that there is no significant reduction in the luminescence intensity upon addition of a 10(4) excess of Ca2+ ions, indicating that this paramagnetic tag is compatible with buffers containing high concentrations of divalent alkaline earth ions.

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Chromosome segregation in Archaea mediated by a hybrid DNA partition machine

Kalliomaa-Sanford

Rodríguez-Castañeda²,

McLeod³

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

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Eukarya and, more recently, some bacteria have been shown to rely on a cytoskeleton-based apparatus to drive chromosome segregation. In contrast, the factors and mechanisms underpinning this fundamental process are underexplored in archaea, the third domain of life. Here we establish that the archaeon Sulfolobus solfataricus harbors a hybrid segrosome consisting of two interacting proteins, SegA and SegB, that play a key role in genome segregation in this organism. SegA is an ortholog of bacterial, Walker-type ParA proteins, whereas SegB is an archaea-specific factor lacking sequence identity to either eukaryotic or bacterial proteins, but sharing homology with a cluster of uncharacterized factors conserved in both crenarchaea and euryarchaea, the two major archaeal sub-phyla. We show that SegA is an ATPase that polymerizes in vitro and that SegB is a site-specific DNA-binding protein contacting palindromic sequences located upstream of the segAB cassette. SegB interacts with SegA in the presence of nucleotides and dramatically affects its polymerization dynamics. Our data demonstrate that SegB strongly stimulates SegA polymerization, possibly by promoting SegA nucleation and accelerating polymer growth. Increased expression levels of segAB resulted in severe growth and chromosome segregation defects, including formation of anucleate cells, compact nucleoids confined to one half of the cell compartment and fragmented nucleoids. The overall picture emerging from our findings indicates that the SegAB complex fulfills a crucial function in chromosome segregation and is the prototype of a DNA partition machine widespread across archaea.nucleoid | polymerization | segrosome | Sulfolobus | Walker-type ParA

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