Jessie M. Zgurski scite author profile

We use multiple photosynthetic, chlororespiratory, and plastid translation apparatus loci and their associated noncoding regions (ca. 16 kb per taxon, prior to alignment) to make strongly supported inferences of the deep internal branches of monocot phylogeny. Most monocot relationships are robust (an average of ca. 91 % bootstrap support per branch examined), including those poorly supported or unresolved in other studies. Our data strongly support a sister-group relationship between Asparagales and the commelinid monocots, the inclusion of the orchids in Asparagales, and the status of Petrosaviaceae as the sister group of all monocots except Acarus and Alismatales. The latter finding supports recognition of the order Petrosaviales. Also strongly supported is a placement of Petermannia disjunct from Colchicaceae (Liliales) and a sister-group relationship between Commelinales and Zingiberales. We highlight the remaining weak areas of monocot phylogeny, including the positions of Dioscoreales, Liliales, and Pandanales. Despite substantial variation in the overall rate of molecular evolution among lineages, inferred amounts of change among codon-position data partitions are correlated with each other across the monocot tree, consistent with low incongruence between these partitions. Ceratophyllum and Chloranthaceae appear to have a destabilizing effect on the position of the monocots among other angiosperms; the issue of monocot placement in broader angiosperm phylogeny remains problematic.

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Asymmetric Auxin Response Precedes Asymmetric Growth and Differentiation of asymmetric leaf1 and asymmetric leaf2 Arabidopsis Leaves

Zgurski

Sharma

Bolokoski

et al. 2004

Plant Cell

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We have analyzed the development of leaf shape and vascular pattern in leaves mutant for ASYMMETRIC LEAVES1 (AS1) or AS2 and compared the timing of developmental landmarks to cellular response to auxin, as measured by expression of the DR5:b-glucuronidase (GUS) transgene and to cell division, as measured by expression of the cycB1:GUS transgene. We found that the earliest visible defect in both as1 and as2 first leaves is the asymmetric placement of auxin response at the distal leaf tip. This precedes visible changes in leaf morphology, asymmetric placement of the distal margin gap, formation of margin gaps along the leaf border, asymmetric distribution of marginal auxin, and asymmetry in cell division patterns. Moreover, treatment of developing leaves with either exogenous auxin or an auxin transport inhibitor eliminates asymmetric auxin response and subsequent asymmetric leaf development. We propose that the initial asymmetric placement of auxin at the leaf tip gives rise to later asymmetries in the internal auxin sources, which subsequently result in asymmetrical cell differentiation and division patterns.

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How well do we understand the overall backbone of cycad phylogeny? New insights from a large, multigene plastid data set

Zgurski

Hardeep

Fai

et al. 2008

Molecular Phylogenetics and Evolution

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Polygynandry and even-sexed dispersal in a population of collared pikas, Ochotona collaris

Zgurski

Hik

2012

Animal Behaviour

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Gene flow and the restoration of genetic diversity in a fluctuating collared pika (Ochotona collaris) population

Zgurski

Hik

2013

Conserv Genet

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Isolation and characterization of microsatellite loci for the collared pika (Ochotona collaris) and their cross‐amplification in five other Ochotona species

Zgurski

Davis

Hik

2009

Molecular Ecology Resources

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We developed primers for eight polymorphic microsatellite loci isolated from the collared pika, Ochotona collaris, and also tested nine loci previously developed for the American pika, O. princeps, for use in O. collaris. Forty-six individuals from an O. collaris population in the southern Yukon were genotyped using all 17 loci. The average number of alleles per locus was six and the average observed heterozygosity was 0.59. All loci were tested for use in four Asian pika species and all but two loci amplified reliably in these species.

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The mating system, dispersal behavior and genetic structure of a collared pika (Ochotona collaris: Ochotonidae) population in the southwest Yukon, and a phylogeny of the genus Ochotona.

Zgurski¹

2011

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Jessie M. Zgurski

Robust Inference of Monocot Deep Phylogeny Using an Expanded Multigene Plastid Data Set

Asymmetric Auxin Response Precedes Asymmetric Growth and Differentiation of asymmetric leaf1 and asymmetric leaf2 Arabidopsis Leaves

How well do we understand the overall backbone of cycad phylogeny? New insights from a large, multigene plastid data set

Polygynandry and even-sexed dispersal in a population of collared pikas, Ochotona collaris

Gene flow and the restoration of genetic diversity in a fluctuating collared pika (Ochotona collaris) population

Isolation and characterization of microsatellite loci for the collared pika (Ochotona collaris) and their cross‐amplification in five other Ochotona species

The mating system, dispersal behavior and genetic structure of a collared pika (Ochotona collaris: Ochotonidae) population in the southwest Yukon, and a phylogeny of the genus Ochotona.

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