Population genetic structure of annual and perennial populations of<i>Zostera marina</i>L. along the Pacific coast of Baja California and the Gulf of California

Muñíz-Salazar, Raquel; Talbot, Sandra L.; Sage, George K.; Ward, David H.; Cabello‐Pasini, Alejandro

doi:10.1111/j.1365-294x.2005.02454.x

Cited by 60 publications

(65 citation statements)

References 74 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…While this will promote strong differentiation at the local scale, connectivity among patchesby incoming dispersal from rafted, fertile seeds -neutralizes this effect. Similar examples of locally high F IS have been found in other European (Olsen et al 2004) and Pacific-Mexican populations (Muniz-Salazar et al 2005) of Z. marina. Alternative explanations for elevated F IS values, such as null alleles, have been ruled out by extensive analyses (Olsen et al 2004), and Wahlund effects, though never completely ruled out, seem unlikely here given, the level of population differentiation observed.…”

Section: High Standing Variation and Clonal Diversitysupporting

confidence: 81%

Genetic diversity and connectivity remain high in eelgrass Zostera marina populations in the Wadden Sea, despite major impacts

Ferber

Stam

Olsen

2008

Mar. Ecol. Prog. Ser.

View full text Add to dashboard Cite

Beginning in the 1930s, eelgrass meadows declined throughout the Wadden Sea, leaving populations susceptible to extinction through patchiness, low density and isolation. Additional anthropogenic impacts have altered current regimes, nutrients and turbidity -al l of which affect eelgrass. Recent abiotic modeling studies suggest that poor recovery is the result of a regime shift caused by the loss of positive feedbacks between seagrass meadows and their capacity to mediate turbidity. Additionally, it is hypothesized that genetic and demographic factors -in particular, the loss of genetic diversity and patch connectivity -have contributed to lower fitness of eelgrass, thereby further diminishing recovery potential. We assessed genetic diversity and connectivity of Zostera marina among 19 locations, covering some 950 km of coastline between Zeeland, Netherlands and Langhölmen, Sweden. Both allelic and genotypic diversity were high. A Bayesian analysis of population structure revealed 6 significant clusters of subpopulations that are connected by varying degrees of dispersal. Although population divergence was significant at as little as 5 km, isolation by distance was very weak, indicating high connectivity at scales of 150 km. A demographic interpretation of these data suggests that realized gene flow is strong and predominantly northward, leaving the western Wadden Sea relatively isolated. The failure of eelgrass to recover in the western Wadden Sea is, therefore, due to both unsuitable physical conditions and low incoming gene flow. Nonetheless, the greater Wadden Sea can be considered a seed transfer zone providing source material for restoration efforts in any areas where abiotic conditions are more favorable.KEY WORDS: Eelgrass · Zostera marina · Genetic diversity · Connectivity · Fragmentation · Dispersal rate · Wadden Sea Resale or republication not permitted without written consent of the publisherMar Ecol Prog Ser 372: [87][88][89][90][91][92][93][94][95][96] 2008 dynamics and geomorphology) and the genetic potential of the populations (genetic variation, population structure and connectivity in relation to mating systems and demography). Integration of these 2 factors is a major goal in a management context (Ouborg et al. 2006), and the power of this integration in eelgrass conservation and biodiversity is exemplified in studies that have modeled the importance of positive feedbacks between eelgrass and turbidity in the Wadden Sea (van der Heide et al. 2007) and manipulative experiments documenting the importance of genetic diversity to enhanced ecosystem function in response to disturbance (Reusch 2006) and to global warming (Reusch et al. 2005).Over the past decade, population genetic studies of eelgrass have been greatly facilitated by the development of neutral microsatellite loci. Eelgrass reproduces both sexually and vegetatively with the consequence that the many shoots (ramets) produced in a particular area may or may not correspond to individual genotypes (genets). Thus, one of the f...

show abstract

Section: High Standing Variation and Clonal Diversitysupporting

confidence: 81%

Genetic diversity and connectivity remain high in eelgrass Zostera marina populations in the Wadden Sea, despite major impacts

Ferber

Stam

Olsen

2008

Mar. Ecol. Prog. Ser.

View full text Add to dashboard Cite

show abstract

“…Measures of genetic diversity offer an alternative for the assessment of conservation value in seagrass habitats [43]; results provided here closely match a growing trend in which eelgrass populations are shown to be more genetically diverse than anticipated [17,29,41]. Two similar studies [40,44] empirically tested the role of genetic diversity in a seagrass population's ability to recover from disturbances.…”

Section: Discussionsupporting

confidence: 53%

“…In analyses of microsatellite loci, awareness of the effect null alleles may have upon results is worthwhile [39]. Like most foundational studies on eelgrass genetics [13,29,40,41], an estimate of null alleles was not employed here. In one study that did estimate the effect of null alleles, Campanella et al [30] found little influence by null alleles upon computed -statistics.…”

Section: Plotmentioning

confidence: 99%

Edge Effects and the Population Structure of Humboldt Bay, California, Eelgrass (Zostera marinaL.)

Neely

2014

International Journal of Ecology

View full text Add to dashboard Cite

The physical structure of a habitat (e.g., fragmentation) may affect the distribution of genetic diversity within a population, and genetic diversity may alter ecological function. This study investigates the population genetics of Humboldt Bay, California, eelgrass in light of the habitat's fragmented physical structure. Historical and ongoing dredging operations in the bay maintain channels between fragmented tidal mudflats that are inhabited by eelgrass. A sample of 469 individuals, from 11 discrete fragments, was genotyped using microsatellite analysis. Ramets were collected at multiple points located at the edge and in the interior of each fragment. The sampling scheme was designed to detect evidence of population structure within and between fragments, as well as between edge and interior bed positions. Genetic diversity is not shown to differ among fragments and is not consistent with widespread clonality. Heterozygosity levels indicate that Hardy-Weinberg equilibrium predominates across loci in most instances. Comparisons of edge and interior bed positions also reveal similarities between positions for the metrics described above. Results suggest efficient gene flow between fragments and between bed positions. Such findings, which indicate the unstructured nature of the population, can guide resource managers in making evolutionarily informed conservation decisions by discouraging assumptions of low genetic diversity and insignificant sexual reproduction.

show abstract

“…This was not the case. Although only qualitative comparisons of mean Â can be made due to differences in normalization and the number of loci used across studies, the mean of 4.78 (Table 1) for the southern California mainland populations is within the estimates of Â for Z. marina populations along the US Pacific coast, i.e., San Juan Is, WA (2.74; Wyllie-Echeverria et al, 2010), Bodega Bay, CA (5.81; Olsen et al, 2004), San Francisco Bay (4.29; Ort et al, 2012), and Baja California, Mexico (4.74;Muniz-Salazar et al, 2005). In the global context, where >150 locations have been surveyed worldwide, the highest diversities found with these loci have been in (Pritchard et al, 2000).…”

Section: A Closer Look At Diversitysupporting

confidence: 55%

Numerous mitigation transplants of the eelgrass Zostera marina in southern California shuffle genetic diversity and may promote hybridization with Zostera pacifica

Olsen¹,

Coyer²,

Chesney³

2014

Biological Conservation

View full text Add to dashboard Cite

Population genetic structure of annual and perennial populations ofZostera marinaL. along the Pacific coast of Baja California and the Gulf of California

Cited by 60 publications

References 74 publications

Genetic diversity and connectivity remain high in eelgrass Zostera marina populations in the Wadden Sea, despite major impacts

Genetic diversity and connectivity remain high in eelgrass Zostera marina populations in the Wadden Sea, despite major impacts

Edge Effects and the Population Structure of Humboldt Bay, California, Eelgrass (Zostera marinaL.)

Numerous mitigation transplants of the eelgrass Zostera marina in southern California shuffle genetic diversity and may promote hybridization with Zostera pacifica

Contact Info

Product

Resources

About