Harper, James T. | DOOR - DOuglas Open Repository

Photograph

Person Preferred Name

James Todd Harper

Position

Faculty Member

Field of Activity

Molecular Evolution Systematics

Marine Biology

Email/Contact

harpert@douglascollege.ca

Department

Biology

Science and Technology

Status

current

Education and Credentials

PhD (New Brunswick)
MSc (St. Francis Xavier)
BSc (St. Francis Xavier)
BA (St. Francis Xavier)

Related Works

Nucleus-encoded, plastid-targeted glyceraldehyde-3-phosphate dehydrogenase (GAPDH) indicates a single origin for chromalveolate plastids

Digital Document

Plastids (the photosynthetic organelles of plants and algae) originated through endosymbiosis between a cyanobacterium and a eukaryote and subsequently spread to other eukaryotes by secondary endosymbioses between two eukaryotes. Mounting evidence favors a single origin for plastids of apicomplexans, cryptophytes, dinoflagellates, haptophytes, and heterokonts (together with their nonphotosynthetic relatives, termed chromalveolates), but so far, no single molecular marker has been described that supports this common origin. One piece of evidence comes from plastid-targeted glyceraldehyde-3-phosphate dehydrogenase (GAPDH), which originated by a gene duplication of the cytosolic form. However, no plastid GAPDH has been characterized from haptophytes, leaving an important piece of the puzzle missing. We have sequenced genes encoding cytosolic, mitochondrion-targeted, and plastid-targeted GAPDH proteins from a number of haptophytes and heterokonts and found haptophyte homologs that branch within a strongly supported clade of chromalveolate plastid-targeted genes, being more closely related to an apicomplexan homolog than was expected. The evolution of plastid-targeted GAPDH supports red algal ancestry of apicomplexan plastids and raises a number of questions about the importance of plastid loss and the possibility of cryptic plastids in nonphotosynthetic lineages such as ciliates.

Using molecular data to resolve the taxonomic limits of the genera Callophyllis , Euthora and Pugetia (Kallymeniaceae, Rhodophyta)

Digital Document

Callophyllis is the largest genus in the red algal family Kallymeniaceae and includes over 50 described species. Since its description, there has been considerable debate over the circumscription of this genus relative to related genera. Specifically, the genus Euthora has sometimes been placed in synonymy with Callophyllis , and a number of species of Pugetia have been transferred to Callophyllis. Phylogenetic analyses based on sequences of nuclear large-subunit ribosomal DNA for representatives of the Kallymeniaceae were completed to assess the various taxonomic proposals surrounding Callophyllis , Euthora and Pugetia . Results indicate that the genus Callophyllis (as generally recognized) is polyphyletic. Callophyllis cristata occupies a position in the trees separate from the remainder of Callophyllis species (including the type Callophyllis variegata ), supporting recognition of Euthora as a distinct genus. Callophyllis chilensis and Callophyllis firma group with the type species of Pugetia , Pugetia fragilissima , thus confirming an earlier taxonomic decision to include these species in the latter genus. A discussion of the relative merits of various reproductive versus vegetative features for assigning species among these three genera is provided. Though outside the scope of the current study, relationships among species of Callophyllis sensu stricto must be visited in light of the results. Although the remaining six species of Callophyllis included in the present trees unequivocally form a monophyletic group, two isolates identified as Callophyllis pinnata (from California and Chile) do not group together, illustrating the confusion generated from the morphological variation within this genus. [ABSTRACT FROM AUTHOR]

Phylogenetic study of the Nemaliales (Rhodophyta) based on large-subunit ribosomal DNA sequences supports segregation of the Scinaiaceae fam. nov. and resurrection of Dichotomaria Lamarck

Digital Document

Gene sequence data have been newly obtained for 18 species in 13 genera of the order Nemaliales (Rhodophyta), allowing for the first time a relatively comprehensive molecular phylogenetic appraisal of the order. The phylogenetic trees generated from these data support the recognition of three families: (i) the Liagoraceae as presently constituted; (ii) a reduced Galaxauraceae includingActinotrichia,Galaxaura (sensu lato), andTricleocarpa; and (iii) a new family, Scinaiaceae, segregated from the Galaxauraceae and including the generaScinaia,Gloiophloea,Nothogenia, and probablyWhidbeyella. The four genera of the Scinaiaceae differ from the newly circumscribed Galaxauraceae in being uncalcified, and having heteromorphic life histories in which the tetrasporophyte is much reduced and filamentous or crustose. This type of life history is found in onlyTricleocarpaof the Galaxauraceae. The results also showGalaxaurato be para/polyphyletic ifActinotrichiaandTricleocarpaare recognized. To remedy this, theGalaxaura marginataspecies complex,Galaxaura diesingiana, andGalaxaura obtusataare removed from the genus and placed in the resurrectedDichotomariaLamarck.Galaxaura marginata, presently thought to be wide-ranging and morphologically variable, is shown to comprise several species. As a consequence,Galaxaura teneraKjellman andBrachycladia australisSonder are removed from the synonymy ofG. marginataand restored as independent species inDichotomariafor South African and Australian isolates, respectively. The Liagoraceae is shown to encompass genera previously placed in the segregate families Nemaliaceae and Dermonemataceae, and the value of the reproductive characters used to define those taxa is discussed. [ABSTRACT FROM AUTHOR]

Large subunit rDNA and rbcL gene sequence data place Petrohua bernabei gen. et sp. nov. in the Batrachospermales (Rhodophyta), but do not provide further resolution among taxa in this order

Digital Document

The phylogenetic relationship among 12 previously described batrachospermalean taxa and a novel member of the order were investigated using the LSU and rbcL genes separately and in combination. The primary goal of this research was to establish the phylogenetic placement of a previously undescribed freshwater red alga from Chile. The results showed that the new entity with pseudoparenchymatous tube morphology is a member of the Batrachospermales and Petrohua bernabei gen. et sp. nov. is described herein. This is the first record to our knowledge of a Lemanea-like alga from Chile. It would appear that this thallus construction has evolved at least three times in the Batrachospermales and that the switch from a Batrachospermum-like construction to a pseudoparenchymatous construction may be a repeated adaptive response to turbulent waterfall habitats. In addition to providing information about a new freshwater red alga, this study sought to determine whether combining the data from two genes would produce a more robust phylogeny, particularly for intermediate nodes, to resolve familial relationships within the order. As with previous analyses, the Batrachospermales was resolved as a clade and support was high for relationships resolved among relatively recent nodes. Unfortunately, combining the LSU and rbcL data did not have the desired effect of more fully resolving intermediate nodes among the Batrachospermales. [ABSTRACT FROM AUTHOR]

New species of Spirotrichonympha from reticulitermes and the relationships among genera in Spirotrichonymphea (Parabasalia)

Digital Document

Spirotrichonymphea is a class of hypermastigote parabasalids defined by their spiral rows of many flagella. They are obligate hindgut symbionts of lower termites. Despite more than 100 yr of morphological and ultrastructural study, the group remains poorly characterised by molecular data and the phylogenetic positions and taxonomic validity of most genera remain in question. The genus Spirotrichonympha has been reported to inhabit several termite genera, including Reticulitermes, Coptotermes, and Hodotermopsis. The type species for this genus, Spirotrichonympha flagellata, was described from Reticulitermes lucifugus but no molecular data are yet available for this species. In this study, three new Spirotrichonympha species are described from three species of Reticulitermes. Their molecular phylogenetic position indicates that the genus is not monophyletic, as Spirotrichonympha species from Coptotermes, Paraneotermes, and Hodotermopsis branch separately. In contrast, the genus Holomastigotoides is monophyletic, as demonstrated using new sequences from Holomastigotoides species. The presence of Holomastigotoides in Prorhinotermes and the distinct phylogenetic positions of Spirotrichonympha from Reticulitermes and Coptotermes are consistent with a previously proposed symbiont fauna replacement in the ancestor of Reticulitermes. [ABSTRACT FROM AUTHOR]

Plastid-derived Type II fatty acid biosynthetic enzymes in chromists

Digital Document

Fatty acid biosynthesis is a critical process for living organisms, but the evolution of the enzymes involved in this pathway is poorly understood. Animals and fungi use a Type I fatty acid synthase (FAS), a large multifunctional protein found in the cytosol. Bacteria use a Type II complex, where each enzymatic domain is a discrete polypeptide. In plants, fatty acid biosynthesis takes place in the plastid, and utilises a Type II enzyme complex. Recently, the apicomplexan parasites Plasmodium and Toxoplasma have been shown to contain the plastid-targeted Type II FAS. To investigate the distribution of this pathway, we have characterised two Type II enzymes, FabD and FabI, in three other eukaryotes with plastids derived from red algal endosymbionts: cryptomonads, heterokonts, and haptophytes. Collectively, these are referred to as chromists, and are thought to be related to apicomplexa and their relatives. Phylogenies of these enzymes show that the plastid Type II FAS enzymes are found in all groups studied, which most likely means that they originated from the red algal endosymbiont at the outset of the secondary endosymbiosis of their plastids. In addition, although plastid fab D genes are clearly related to one another, they are not related to cyanobacterial homologues, as would be expected. On the other hand, the strongly supported plastid fab I clade is related to cyanobacteria, and contains genes from chlamydiales. [ABSTRACT FROM AUTHOR]

Lateral gene transfer and the complex distribution of insertions in eukaryotic enolase

Digital Document

Insertions and deletions in protein-coding genes are relatively rare events compared with sequence substitutions because they are more likely to alter the tertiary structure of the protein. For this reason, insertions and deletions which are clearly homologous are considered to be stable characteristics of the proteins where they are found, and their presence and absence has been used extensively to infer large-scale evolutionary relationships and events. Recently, however, it has been shown that the pattern of highly conserved, clearly homologous insertions at positions with no other detectable homoplasy can be incongruent with the phylogeny of the genes or organisms in which they are found. One case where this has been reported is in the enolase genes of apicomplexan parasites and ciliates, which share homologous insertions in a highly conserved region of the gene with the apparently distantly related enolases of plants. Here we explore the distribution of this character in enolase genes from the third major alveolate group, the dinoflagellates, as well as two groups considered to be closely related to alveolates, haptophytes and heterokonts. With these data, all major groups of the chromalveolates are represented, and the distribution of these insertions is shown to be far more complicated than previously believed. The incongruence between this pattern, the known evolutionary relationships between the organisms, and enolase phylogeny itself cannot be explained by any single event or type of event. Instead, the distribution of enolase insertions is more likely the product of several forces that may have included lateral gene transfer, paralogy, and/or recombination. Of these, lateral gene transfer is the easiest to detect and some well-supported cases of eukaryote-to-eukaryote lateral transfer are evident from the phylogeny. [ABSTRACT FROM AUTHOR]

Molecular systematics of the Florideophyceae (Rhodophyta) using nuclear large- and small-subunit ribosomal DNA sequence data

Digital Document

Sequence data are presented for approximately 85% of the nuclear large subunit (LSU) rDNA gene for one member of the Bangiophyceae and 47 members of the Florideophyceae, the latter representing all but one of the currently recognized florideophyte orders. Distance, parsimony, and maximum likelihood analyses of these data were used to generate phylogenetic trees, and bootstrap resampling was implemented to infer robustness for distance and parsimony results. LSU phylogenies were congruent with published nuclear small subunit (SSU) rDNA results in that four higher level florideophyte lineages were resolved: lineage 1, containing the order Hildenbrandiales; lineage 2, recovered only under distance analysis, composed of the orders Acrochaetiales, Balliales, Batrachospermales, Corallinales, Nemaliales, Palmariales, and Rhodogorgonales; lineage 3, containing the Ahnfeltiales; and lineage 4, composed of the orders Bonnemaisoniales, Ceramiales, Gelidiales, Gigartinales, Gracilariales, Halymeniales, Plocamiales, and Rhodymeniales. Analyses were also performed on a combined LSU–SSU data set and an SSU-only data set to account for differences in taxon sampling relative to published studies using this latter gene. Combined LSU–SSU analyses resulted in phylogenetic trees of similar topology and support to those obtained from LSU-only analyses. Phylogenetic trees produced from SSU-only analyses differed somewhat in particulars of branching within lineages 2 and 4 but overall were congruent with the LSU-only and combined LSU–SSU results. We close with a discussion of the phylogenetic potential that the LSU has displayed thus far for resolving relationships within the Florideophyceae. [ABSTRACT FROM AUTHOR]

The inadequacy of morphology for species and genus delineation in microbial eukaryotes

Digital Document

Background For the majority of microbial eukaryotes (protists, algae), there is no clearly superior species concept that is consistently applied. In the absence of a practical biological species concept, most species and genus level delineations have historically been based on morphology, which may lead to an underestimate of the diversity of microbial eukaryotes. Indeed, a growing body of molecular evidence, such as barcoding surveys, is beginning to support the conclusion that significant cryptic species diversity exists. This underestimate of diversity appears to be due to a combination of using morphology as the sole basis for assessing diversity and our inability to culture the vast majority of microbial life. Here we have used molecular markers to assess the species delineations in two related but morphologically distinct genera of uncultivated symbionts found in the hindgut of termites. Methodology/Principal Findings Using single-cell isolation and environmental PCR, we have used a barcoding approach to characterize the diversity of Coronympha and Metacoronympha symbionts in four species of Incisitermes termites, which were also examined using scanning electron microscopy and light microcopy. Despite the fact that these genera are significantly different in morphological complexity and structural organisation, we find they are two life history stages of the same species. At the same time, we show that the symbionts from different termite hosts show an equal or greater level of sequence diversity than do the hosts, despite the fact that the symbionts are all classified as one species. Conclusion/Significance The morphological information used to describe the diversity of these microbial symbionts is misleading at both the genus and species levels, and led to an underestimate of species level diversity as well as an overestimate of genus level diversity. The genus ‘Metacoronympha’ is invalid and appears to be a life history stage of <i>Coronympha</i>, while the single recognized species of <i>Coronympha octonaria,</i> inhabiting these four termites is better described as four distinct species.

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