α‐Proteobacterial Relationship of Apicomplexan Lactate and Malate Dehydrogenases

Zhu, Guangxi; Keithly, Janet S.

doi:10.1111/j.1550-7408.2002.tb00532.x

Cited by 31 publications

(27 citation statements)

References 29 publications

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“…A maximum likelihood phylogeny of representatives of all known LDH and MDH proteins provides strong support for five distinct protein clades (Figure 3A, Figure 3—figure supplement 1): canonical LDHs, ‘LDH-like’ MDHs, mitochondrial-like MDHs, cytosolic-like MDHs, and the poorly characterized HicDHs (hydroxyisocaproate-related dehydrogenases), confirming previous phylogenetic analyses (Golding and Dean, 1998; Madern, 2002; Zhu and Keithly, 2002; Madern et al, 2004). …”

Section: Resultssupporting

confidence: 79%

“…A key event in the early evolution of the Apicomplexa was the acquisition of a malate dehydrogenase (MDH) via lateral gene transfer from α-proteobacteria (Golding and Dean, 1998; Madern, 2002; Zhu and Keithly, 2002). Following a gene duplication event roughly 700–900 Mya, one copy of this MDH evolved a novel substrate specificity to become a highly specific lactate dehydrogenase (LDH) that is now essential to the life cycle of many modern apicomplexans (Royer et al, 1986).…”

Section: Introductionmentioning

confidence: 99%

“…Apicomplexan LDH evolved from the duplication of an ancestral MDH gene (Golding and Dean, 1998; Zhu and Keithly, 2002). Gene duplication is widely considered the major force that has driven the evolutionary diversity of protein functions (Innan and Kondrashov, 2010).…”

Section: Introductionmentioning

confidence: 99%

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An atomic-resolution view of neofunctionalization in the evolution of apicomplexan lactate dehydrogenases

Boucher

Jacobowitz

Beckett

et al. 2014

eLife

116

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Malate and lactate dehydrogenases (MDH and LDH) are homologous, core metabolic enzymes that share a fold and catalytic mechanism yet possess strict specificity for their substrates. In the Apicomplexa, convergent evolution of an unusual LDH from MDH produced a difference in specificity exceeding 12 orders of magnitude. The mechanisms responsible for this extraordinary functional shift are currently unknown. Using ancestral protein resurrection, we find that specificity evolved in apicomplexan LDHs by classic neofunctionalization characterized by long-range epistasis, a promiscuous intermediate, and few gain-of-function mutations of large effect. In canonical MDHs and LDHs, a single residue in the active-site loop governs substrate specificity: Arg102 in MDHs and Gln102 in LDHs. During the evolution of the apicomplexan LDH, however, specificity switched via an insertion that shifted the position and identity of this ‘specificity residue’ to Trp107f. Residues far from the active site also determine specificity, as shown by the crystal structures of three ancestral proteins bracketing the key duplication event. This work provides an unprecedented atomic-resolution view of evolutionary trajectories creating a nascent enzymatic function.DOI: http://dx.doi.org/10.7554/eLife.02304.001

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Section: Resultssupporting

confidence: 79%

Section: Introductionmentioning

confidence: 99%

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An atomic-resolution view of neofunctionalization in the evolution of apicomplexan lactate dehydrogenases

Boucher

Jacobowitz

Beckett

et al. 2014

eLife

116

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“…1) relative to many sequenced eukaryotes (Carlton et al 2002, 2008; Gardner et al 2002, 2005; Abrahamsen et al 2004; Brayton et al 2007). They are characterized by gene loss (Kuo and Kissinger 2008), with only a few thousand protein-encoding genes per genome and both intracellular and lateral gene transfer (Zhu and Keithly 2002; Huang, Mullapudi, Lancto, et al 2004; Huang, Mullapudi, Sicheritz-Ponten, and Kissinger 2004; Striepen et al 2004; Huang and Kissinger 2006; Nagamune and Sibley 2006). The most striking example of gene loss to date is found in Cryptosporidium parvum , where all pathways for de novo nucleotide synthesis have been lost and nucleotide salvage pathways have been acquired (Striepen et al 2004).…”

Section: Introductionmentioning

confidence: 99%

Jumbled Genomes: Missing Apicomplexan Synteny

DeBarry

Kissinger

2011

Molecular Biology and Evolution

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Whole-genome comparisons provide insight into genome evolution by informing on gene repertoires, gene gains/losses, and genome organization. Most of our knowledge about eukaryotic genome evolution is derived from studies of multicellular model organisms. The eukaryotic phylum Apicomplexa contains obligate intracellular protist parasites responsible for a wide range of human and veterinary diseases (e.g., malaria, toxoplasmosis, and theileriosis). We have developed an in silico protein-encoding gene based pipeline to investigate synteny across 12 apicomplexan species from six genera. Genome rearrangement between lineages is extensive. Syntenic regions (conserved gene content and order) are rare between lineages and appear to be totally absent across the phylum, with no group of three genes found on the same chromosome and in the same order within 25 kb up- and downstream of any orthologous genes. Conserved synteny between major lineages is limited to small regions in Plasmodium and Theileria/Babesia species, and within these conserved regions, there are a number of proteins putatively targeted to organelles. The observed overall lack of synteny is surprising considering the divergence times and the apparent absence of transposable elements (TEs) within any of the species examined. TEs are ubiquitous in all other groups of eukaryotes studied to date and have been shown to be involved in genomic rearrangements. It appears that there are different criteria governing genome evolution within the Apicomplexa relative to other well-studied unicellular and multicellular eukaryotes.

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“…Some, such as those of Entamoeba and Cryptosporidium, have been shown to contain chaperonin Cpn60, a protein known to participate in the refolding of imported proteins (Sigler et al, 1998; Mai et al, 1999;Tovar et al, 1999;Riordan et al, 2003); mitosomes of Trachipleistophora contain a mitochondrialtype Hsp70 (mtHsp70), a molecular motor that helps internalize proteins into the organelle (Matouschek et al, 2000;Williams et al, 2002). Other proteins have also been suggested as putative mitosomal components in various amitochondrial lineages but their cellular localization has not been demonstrated experimentally (Clark & Roger, 1995;Bakatselou et al, 2000Bakatselou et al, , 2003Katinka et al, 2001;Morrison et al, 2001;Zhu & Keithly, 2002;Arisue et al, 2002). Perhaps the most significant finding in relation to the biology of mitosomes is the direct demonstration that Giardia mitosomes function in the biosynthesis of molecular iron-sulphur (Fe-S) clusters and in their subsequent incorporation into functional Fe-S proteins (Tovar et al, 2003).…”

mentioning

confidence: 99%

Mitosomes of Entamoeba histolytica are abundant mitochondrion-related remnant organelles that lack a detectable organellar genome

León-Ávila

Tovar

2004

Microbiology

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The existence of mitochondrion-related relict organelles (mitosomes) in the amitochondrial human pathogen Entamoeba histolytica and the detection of extranuclear DNA-containing cytoplasmic structures (EhKOs) has led to the suggestion that a remnant genome from the original mitochondrial endosymbiont might have been retained in this organism. This study reports on the mutually exclusive distribution of Cpn60 and extranuclear DNA in E. histolytica and on the distribution of Cpn60-containing mitosomes in this parasite. In situ nick-translation coupled to immunofluorescence microscopy failed to detect the presence of DNA in mitosomes, either in fixed parasite trophozoites or in partially purified organellar fractions. These results indicate that a remnant organellar genome has not been retained in E. histolytica mitosomes and demonstrate unequivocally that EhKOs and mitosomes are distinct and unrelated cellular structures. INTRODUCTIONOver the past few years mitochondrial remnant organelles (mitosomes) have been identified in a number of amitochondrial parasitic protozoa (e.g. Giardia intestinalis, Entamoeba histolytica, Trachipleistophora hominis and Cryptosporidium parvum) (Mai et al., 1999;Tovar et al., 1999Tovar et al., , 2003Williams et al., 2002;Riordan et al., 2003), disproving the Archezoa hypothesis, which postulated that amitochondrial eukaryotic organisms were the direct descendants of the nucleated cell that hosted the original mitochondrial endosymbiont (Cavalier-Smith, 1983, 1998. It is now apparent that eukaryotic microbes that lack typical mitochondria are not primitively amitochondrial but are highly derived descendants of mitochondrioncontaining ancestors whose capacity for aerobic respiration has been gradually lost during the course of evolution.Because of their recent discovery, little is known about the physiological functions of mitosomes. Some, such as those of Entamoeba and Cryptosporidium, have been shown to contain chaperonin Cpn60, a protein known to participate in the refolding of imported proteins (Sigler et al., 1998; Mai et al., 1999;Tovar et al., 1999;Riordan et al., 2003); mitosomes of Trachipleistophora contain a mitochondrialtype Hsp70 (mtHsp70), a molecular motor that helps internalize proteins into the organelle (Matouschek et al., 2000;Williams et al., 2002). Other proteins have also been suggested as putative mitosomal components in various amitochondrial lineages but their cellular localization has not been demonstrated experimentally (Clark & Roger, 1995;Bakatselou et al., 2000Bakatselou et al., , 2003Katinka et al., 2001;Morrison et al., 2001;Zhu & Keithly, 2002;Arisue et al., 2002). Perhaps the most significant finding in relation to the biology of mitosomes is the direct demonstration that Giardia mitosomes function in the biosynthesis of molecular iron-sulphur (Fe-S) clusters and in their subsequent incorporation into functional Fe-S proteins (Tovar et al., 2003). Genes encoding several proteins involved in Fe-S cluster metabolism have also been identified in the genome...

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α‐Proteobacterial Relationship of Apicomplexan Lactate and Malate Dehydrogenases

Cited by 31 publications

References 29 publications

An atomic-resolution view of neofunctionalization in the evolution of apicomplexan lactate dehydrogenases

An atomic-resolution view of neofunctionalization in the evolution of apicomplexan lactate dehydrogenases

Jumbled Genomes: Missing Apicomplexan Synteny

Mitosomes of Entamoeba histolytica are abundant mitochondrion-related remnant organelles that lack a detectable organellar genome

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