Nurit Yaffe scite author profile

Summary Kinetoplast DNA (kDNA), the trypanosome mitochondrial DNA, contains thousands of minicircles and dozens of maxicircles interlocked in a giant network. Remarkably, Trypanosoma brucei's genome encodes eight PIF1-like helicases, six of which are mitochondrial. We now show that TbPIF2 is essential for maxicircle replication. Maxicircle abundance is controlled by TbPIF2 level, as RNAi of this helicase caused maxicircle loss and its overexpression caused a 3- to 6-fold increase in maxicircle abundance. This regulation of maxicircle level is mediated by the TbHslVU protease. Previous experiments demonstrated that RNAi knockdown of TbHslVU dramatically increased abundance of minicircles and maxicircles, presumably because a positive regulator of their synthesis escaped proteolysis and allowed synthesis to continue. Here we found that TbPIF2 level increases following RNAi of the protease. Therefore this helicase is a TbHslVU substrate and the first example of a positive regulator, thus providing a molecular mechanism for controlling maxicircle replication.

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Interactions of a Replication Initiator with Histone H1-like Proteins Remodel the Condensed Mitochondrial Genome

Kapeller¹,

Milman²,

Yaffe³

et al. 2011

Journal of Biological Chemistry

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Background:The mechanism of kinetoplast DNA (kDNA) remodeling and its function during replication have been unknown. Results: Interactions of the replication initiator protein UMSBP with kDNA-condensing proteins result in kDNA decondensation, promoting its accessibility to topoisomerase II. Conclusion: UMSBP-mediated remodeling may precede and promote the initiation of kDNA replication. Significance: The function of a replication initiator in remodeling a mitochondrial genome is demonstrated.

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Enzymatic Mechanism Controls Redox-mediated Protein-DNA Interactions at the Replication Origin of Kinetoplast DNA Minicircles

Sela¹,

Yaffe²,

Shlomai³

2008

Journal of Biological Chemistry

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Kinetoplast DNA (kDNA) is the mitochondrial DNA of trypanosomatids. Its major components are several thousand topologically interlocked DNA minicircles. Their replication origins are recognized by universal minicircle sequence-binding protein (UMSBP), a CCHC-type zinc finger protein, which has been implicated with minicircle replication initiation and kDNA segregation. Interactions of UMSBP with origin sequences in vitro have been found to be affected by the protein's redox state. Reduction of UMSBP activates its binding to the origin, whereas UMSBP oxidation impairs this activity. The role of redox in the regulation of UMSBP in vivo was studied here in synchronized cell cultures, monitoring both UMSBP origin binding activity and its redox state, throughout the trypanosomatid cell cycle. These studies indicated that UMSBP activity is regulated in vivo through the cell cycle dependent control of the protein's redox state. The hypothesis that UMSBP's redox state is controlled by an enzymatic mechanism, which mediates its direct reduction and oxidation, was challenged in a multienzyme reaction, reconstituted with pure enzymes of the trypanosomal major redox-regulating pathway. Coupling in vitro of this reaction with a UMSBP origin-binding reaction revealed the regulation of UMSBP activity through the opposing effects of tryparedoxin and tryparedoxin peroxidase. In the course of this reaction, tryparedoxin peroxidase directly oxidizes UMSBP, revealing a novel regulatory mechanism for the activation of an origin-binding protein, based on enzyme-mediated reversible modulation of the protein's redox state. This mode of regulation may represent a regulatory mechanism, functioning as an enzyme-mediated, redox-based biological switch.2 is a unique extrachromosomal DNA network, found in the single mitochondrion of trypanosomatids. It consists, in the species Crithidia fasciculata, of ϳ5,000 duplex DNA minicircles of 2.5 kbp and ϳ50 maxicircles of 37 kbp that are interlocked topologically to form a DNA network. Two short sequences, the dodecameric universal minicircle sequence (UMS), GGGGTTGGTGTA, and the hexameric sequence ACGCCC, which were located at the minicircle's replication origin and implicated with its replication initiation, were conserved in all trypanosomatid species studied (recently reviewed in Refs.

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Unique Characteristics of the Kinetoplast DNA Replication Machinery Provide Potential Drug Targets in Trypanosomatids

Sela

Milman

Kapeller

et al.

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Direct monitoring of the stepwise condensation of kinetoplast DNA networks

Yaffe¹,

Rotem

Soni³

et al. 2021

Sci Rep

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Condensation and remodeling of nuclear genomes play an essential role in the regulation of gene expression and replication. Yet, our understanding of these processes and their regulatory role in other DNA-containing organelles, has been limited. This study focuses on the packaging of kinetoplast DNA (kDNA), the mitochondrial genome of kinetoplastids. Severe tropical diseases, affecting large human populations and livestock, are caused by pathogenic species of this group of protists. kDNA consists of several thousand DNA minicircles and several dozen DNA maxicircles that are linked topologically into a remarkable DNA network, which is condensed into a mitochondrial nucleoid. In vitro analyses implicated the replication protein UMSBP in the decondensation of kDNA, which enables the initiation of kDNA replication. Here, we monitored the condensation of kDNA, using fluorescence and atomic force microscopy. Analysis of condensation intermediates revealed that kDNA condensation proceeds via sequential hierarchical steps, where multiple interconnected local condensation foci are generated and further assemble into higher order condensation centers, leading to complete condensation of the network. This process is also affected by the maxicircles component of kDNA. The structure of condensing kDNA intermediates sheds light on the structural organization of the condensed kDNA network within the mitochondrial nucleoid.

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Nurit Yaffe

Trypanosomes Have Six Mitochondrial DNA Helicases with One Controlling Kinetoplast Maxicircle Replication

Interactions of a Replication Initiator with Histone H1-like Proteins Remodel the Condensed Mitochondrial Genome

Enzymatic Mechanism Controls Redox-mediated Protein-DNA Interactions at the Replication Origin of Kinetoplast DNA Minicircles

Unique Characteristics of the Kinetoplast DNA Replication Machinery Provide Potential Drug Targets in Trypanosomatids

Direct monitoring of the stepwise condensation of kinetoplast DNA networks

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