Plant News

Reconstructing the Sudden Oak Death epidemic

2008-04-17T08:20:00.002-05:00

Biology-blog reports on a study that reconstructs the Sudden Oak Death epidemic in California. The paper is due to be published "early online" later this month in the journal Molecular Ecology.

8000-year-old spruce roots

2008-04-09T02:16:00.004-05:00

Martin Rundkvist talks about some recent discoveries

New research by Leif Kullman at the University of Umeå is just being reported on by the media... no standing trees older than 600 years ... But below ground, the living roots of three trees gave radiocarbon dates at 5,000, 6,000 and 8,000 years BP! The oldest root system thus dates back from the end of the latest glaciation.

Pretty cool stuff. Now here's the interesting question - can someone find something similar in an area that wasn't glaciated? What's the real maximum age for individuals like this?

Update: Reed E. in the comments answers that question (though, sadly, without a reference, so take this with a grain of salt)

While the Norway Spruce is a fine tree, its clonal colonies have nothing on the Quaking Aspen (Populus tremuloides.) There's Pando in Utah, a single clonal colony that is thought to weigh 6,000 tonnes and perhaps as old as 80,000 years.

Posted by: Reed E | April 8, 2008 8:14 PM

Tangled Bank #102

2008-04-02T12:56:00.002-05:00

Tangled Bank #102 is up at Further Thoughts. Berry Go Round #3 was published a week ago at Greg Laden's blog.

Berry Go Round #2

2008-02-28T14:49:00.001-06:00

The second edition of Berry Go Round, the plant-focussed blog carnival, is up at my main blog.

Svalbard Global Seed Vault opens

2008-02-26T10:20:00.003-06:00

The Svalbard Global Seed Vault opened today on a remote island in the Arctic Circle, receiving inaugural shipments of 100 million seeds that originated in over 100 countries. With the deposits ranging from unique varieties of major African and Asian food staples such as maize, rice, wheat, cowpea, and sorghum to European and South American varieties of eggplant, lettuce, barley, and potato, the first deposits into the seed vault represent the most comprehensive and diverse collection of food crop seeds being held anywhere in the world.

The purpose of the repository is to preserve crop genetic diversity. I think it's an important project, but is it really enough?

Source: EurekaAlert!

Additional coverage from the New York Times.

New genetic tools for working with peas

2008-02-26T00:24:00.002-06:00

The pea is one of many important crop species that is unsuited to the Agrobacterium-based genetic modification techniques that are commonly used to work with crops. Researchers, reporting in the open access journal Genome Biology have now discovered the first high-throughput forward and reverse genetics tool for the pea (Pisum sativum), could have major benefits for crop breeders around the world..

Researchers from the INRA Plant Genomics Research Unit at Evry, and the INRA Grain Legumes Research Unit at Bretenières, both in France, both in France developed a high-quality genetic reference collection of Pisum sativum mutants within the European Grain Legumes Integrated Project. Abdelhafid Bendahmane and colleagues used plants from an early-flowering garden pea cultivar, Caméor, to create a mutant population, which they then systematically phenotyped for use in both forward and reverse genetics studies.

Source: EurekaAlert!

Composting to fight climate change?

2008-02-26T00:17:00.003-06:00

From EurekaAlert!

Applying organic fertilizers, such as those resulting from composting, to agricultural land could increase the amount of carbon stored in these soils and contribute significantly to the reduction of greenhouse gas emissions, according to new research published in a special issue of Waste Management & Research (Special issue published today by SAGE).
Carbon sequestration in soil has been recognized by the Intergovernmental Panel on Climate Change and the European Commission as one of the possible measures through which greenhouse gas emissions can be mitigated.

One estimate of the potential value of this approach – which assumed that 20% of the surface of agricultural land in the EU could be used as a sink for carbon – suggested it could constitute about 8.6% of the total EU emission-reduction objective.

“An increase of just 0.15% in organic carbon in arable soils in a country like Italy would effectively imply the sequestration of the same amount of carbon within soil that is currently released into the atmosphere in a period of one year through the use of fossil fuels,” write Enzo Favoino and Dominic Hogg, authors of the paper.

The number - 0.15% - seems small, but this is deceptive - it's still an awful lot of carbon. I'd be more interested in the mechanics of how they're going to get this done...but that would probably require actually reading the journal. The press release addresses an important point

However, capitalizing on this potential climate-change mitigation measure is not a simple task. The issue is complicated by the fact that industrial farming techniques mean agriculture is actually depleting carbon from soil, thus reducing its capacity to act as a carbon sink.

but answers this by saying

According to Hogg and Favoino, this loss of carbon sink capacity is not permanent. Composting can contribute in a positive way to the twin objectives of restoring soil quality and sequestering carbon in soils. Applications of organic matter (in the form of organic fertilizers) can lead either to a build-up of soil organic carbon over time, or a reduction in the rate at which organic matter is depleted from soils. In either case, the overall quantity of organic matter in soils will be higher than using no organic fertilizer.

Let us hope it's that simple.

Draft corn genome

2008-02-26T00:10:00.003-06:00

A team of scientists led by Washington University in St. Louis has begun to unlock the genetic secrets of corn, a crop vital to U.S. agriculture. The researchers have completed a working draft of the corn genome, an accomplishment that should accelerate efforts to develop better crop varieties to meet society's growing demands for food, livestock feed and fuel....
The genetic blueprint will be announced on Thursday, Feb. 28, by the project's leader, Richard K. Wilson, Ph.D., director of Washington University's Genome Sequencing Center, at the 50th Annual Maize Genetics Conference in Washington, D.C.

Source: EurekaAlert!

Related: from Iowa State University News Service: Iowa State researchers help piece together the corn genome's first draft

Also, from PhysOrg.com

Invasive plant journal launched

2008-02-22T00:34:00.000-06:00

The Weed Science Society of America has launched a new journal, Invasive Plant Science and Management. The first issue is expected in the first quarter of 2008. The society is soliciting articles in:

[T]he biology and ecology of invasive plants in rangeland, parkland, prairie, pasture, preserve, urban, wildland, forestry, riparian, wetland, aquatic, recreational, rights-of-way, and other non-crop settings; genetics of invasive plants; social, ecological, and economic impacts of invasive plants; design, efficacy, and integration of control tools; land restoration and rehabilitation; effects of management on soil, air, water, and wildlife; scholarship in education, extension, and outreach methods and resources; technology and product reports; mapping and remote sensing, inventory and monitoring; technology transfer tools; and regulatory issues.

A guardian of grasses

2008-02-07T08:03:00.000-06:00

Anoop Sindhu and colleagues report on a gene that may have played a key role in the evolution of grasses. The gene, Hm1, provides resistance against Cochliobolus carbonumrace 1 (CCR1), a fungus that is capable of attacking and killing corn at any stage of its development (images of CCR1 infection). While CCR1 is only known to affect corn, the gene Hm1 and its relatives are present throughout the grass family, but are absent from other lineages.

CCR1 is only known as a disease in Zea mays, but the Hm1 family of genes throughout the grass family. Sindhu and colleagues silenced the corresponding gene in barley. This resulted in barley that was susceptible to CCR1. The fungus is able to invade susceptible grasses through the production of Helminthosporium carbonum* (HC) toxin. The ability of Hm1 and related genes to resist CCR1 comes from an enzyme known as HC-toxinreductase (HCTR), which detoxifies HCTR.

A phylogenetic analysis of the Hm1-gene family showed that they were monophyletic - they all shared a common ancestor. Since it is present throughout the grass family, but is absent from all other groups of plants, it appears that the gene shares its origin with the grass family. This lead the authors to conclude that:

The maintenance of HCTR gene function in maize and barley, coupledwith the unique phylogenetic position of the Hm1 gene (withno closely related orthologs in eudicots), suggests that Hm1may have played a critical role in the evolution of most ofour cereal crops. Given the devastating potential of CCR1 tokill susceptible corn, it is likely that this fungus or itsancestral form would have threatened the existence of grasses,or at least severely constrained their geographical distribution,had Hm1 not evolved to detoxify HC toxin. Thus, it seems likelythat Hm1 served as a guardian of the grass family, allowingit to survive, thrive, and evolve into crops that feed the world.

*Helminthosporium carbonum is the asexual form of Cochliobolus carbonum. Since fungi are classified on the basis of their sexual structure, fungi whose fruiting bodies are unknown often end up being described as distinct species.

Sindhu, A., Chintamanani, S., Brandt, A.S., Zanis, M., Scofield, S.R., Johal, G.S. (2008). A guardian of grasses: Specific origin and conservation of a unique disease-resistance gene in the grass lineage. Proceeding of the National Academy of Sciences USA, 105(5), 1762-1767. DOI: 10.1073/pnas.0711406105 Open Access

Onions without tears

2008-02-06T23:31:00.000-06:00

Using gene silencing, researchers in New Zealand's Crop and Food research institute were able to make onions that don't make you cry when you cut them.

Source: PhysOrg.com

Eat your carrots - you need the calcium

2008-02-06T22:51:00.000-06:00

Food science tends to focus on improving the nutritional quality of foods, but rarely does it look at how these "improved" foods affect human (or animal) health. A group of researchers from Texas A&M University and Baylor College of Medicine looked at whether enriched calcium in foods was actually used by the body. They had previously engineered carrots which had twice the normal level of calcium. In a paper published in the Proceeding of the National Academy of Sciences USA, they looked at the fate of this calcium in the body. By using labelled calcium they were able to observe its eventual fate. Their conclusion:

In a cross-over study of 15 male and 15 female adults, we found that when people were fed sCAX1 and control carrots, total calcium absorption per 100 g of carrots was 41% ± 2% higher in sCAX1 carrots. Both the mice and human feeding studies demonstrate increased calcium absorption from sCAX1-expressing carrots compared with controls. These results demonstrate an alternative means of fortifying vegetables with bioavailable calcium.

Morris,Jay, Hawthorne,Keli M., Hotze, Tim, Abrams Steven A., and Hirschi*, Kendal D. 2008. Nutritional impact of elevated calcium transport activity in carrots. Proceeding of the National Academy of Sciences USA 105(5):1431-1435 DOI:10.1073/pnas.0709005105

Is it really organic?

2008-02-01T23:54:00.001-06:00

It can be difficult to determine whether something is really organic. How can you tell if a producer is calling food organic that isn't? While most persticides are likely to leave residues that could be tested for, fertilisers are more difficult to detect. One possibility is to look for differences in the ratios of stable isotopes of nitrogen - nitrogen. Spanish scientists Francisco del Amora, Joaquín Navarroa and Pedro Aparicio decided to see if they could tell the difference between organic and conventionally grown crops on the basis of nitrogen isotope ratios. They concluded that it was possible to detect fertiliser use.

Agencies for organic farming certification require techniques to verify the organic nature of the N fertilizers applied to crops. Results show that significant differences have been found between organic and not fully organic practices. Thus, this study demonstrates that with N-isotopic techniques it is possible to discriminate the use of chemical fertilizers in the organic production of sweet peppers with respect to strictly nonorganic crops. Further studies including the effects of different soils characteristics, climate, and biotic or abiotic stress could be useful in determining the proper interval of ¹⁵N/¹⁴N ratio to exclude nonorganic fertilization practices.

del Amora,F.M., Navarroa J., and Aparicio, P.M. 2008. Isotopic Discrimination as a Tool for Organic Farming Certification in Sweet Pepper.

Internationally Important Algal Habitats

2008-01-31T12:49:00.000-06:00

Fifteen locations in Britain have been identified as internationally important based on their algal flora.

Among the 15 locations listed is a freshwater area in Cornwall near St. Just that has 100 species of algae, two of which are classified as rare. Another important area is a coastal site at Lundy Island off Devon with 300 species of algae.

Source: PhysOrg.com

Immune systems in plants

2008-01-31T12:41:00.000-06:00

In a review article due to be published in the journal Developmental & Comparative Immunology John M. McDowell and Stacey A. Simona looked at "plant-pathogen interface" and found notable similarities and differences between the molecular immune responses of plants and (metazoan) animals. They concluded that

It now seems clear that plants and animals have independently adopted many of the same protein modules for immune surveillance. Many interesting mechanistic and evolutionary parallels are evident upon comparison of immune surveillance in plants and animals, and we look forward to productive, “cross-species” dialog between animal and plant immunologists in the years to come.

McDowell, J.M. and Simona, S.A. 2008. Molecular diversity at the plant–pathogen interface. Developmental & Comparative Immunology doi:10.1016/j.dci.2007.11.005

Insecticidal compounds in plants

2008-01-30T14:24:00.000-06:00

Several members of three plants families - the Rubiaceae, Violaceae and Cucurbitaceae- produce cyclotides, cyclic mini-peptides made up of 28-37 amino acids arranged in a circular configuration. These compounds are very stable and have attracted the attention of pharmaceutical companies. Because these peptides lack free amino and carboxyl ends, they cannot be broken down by proteases. The compounds appear to act primarily as insecticides. In an article published in the January 29 issue of PNAS, Barbara Barbeta and colleagues investigated the role of these compounds on the larvae of lepidopterans (butterflies and moths). The compounds damaged the cells of the midgut of Helicoverpa armigera larvae, which severely stunted their growth (image from Wikipedia; see license details).

Barbeta, B.L., Marshall, A.T., Gillon, A.D., Craik, D.J., and Anderson, M.A. 2008. Plant cyclotides disrupt epithelial cells in the midgut of lepidopteran larvae. Proceedings of the National Academy of Sciences USA 105(4):1221-1225 DOI:10.1073/pnas.0710338104

Tropical Plant Biology journal launched

2008-01-30T12:52:00.000-06:00

Springer is launching a new journal Tropical Plant Biology. This first issue is due in March 2008. According to the press release, the journal will:

[R]eport on significant advances in all aspects of tropical plant biology as well as applications towards genetic diversity and crop improvement."

Tropical Plant Biology will cover the most rapidly advancing aspects of tropical plant biology including physiology, evolution, development, cellular and molecular biology, cytology, genetics, genomics, comparative genomics, genomic ecology and molecular breeding. It will publish articles of original research as well as review articles. Occasional special issues focused on a single tropical crop species or breakthrough will also be published. The information in this journal will guide efforts to increase the productivity and quality of tropical plants and preserve the world’s plant diversity.

The journal will be edited by Paul H. Moore of the International Consortium for Sugarcane Biotechnology and and Ray Ming of the Department of Plant Biology, University of Illinois at Urbana-Champaign, both of whom focus on tropical crops.

Plastid evolution

2008-01-29T23:48:00.001-06:00

A forthcoming paper in the Annual Review of Plant Biology looks really interesting: Plastid Evolution. Written by Sven Gould, Ross Waller and Geoffrey McFadden of the University of Melbourne, it looks really promising. From the abstract:

We review the origins, integration, and functions of the different plastid types with special emphasis on their biochemical abilities, transfer of genes to the host, and the back supply of proteins to the endosymbiont.

Gould, S.B., Waller, R.F. and McFadden, G.I. 2008. Plastid Evolution. Annual Review of Plant Biology 59

Interactions between Bt crops and mycorrhizal fungi

2008-01-29T17:49:00.001-06:00

In the February issue of Acta Agriculturae Scandinavica, Section B - Soil & Plant Science Liu Wenke and Du Lianfeng raise the question of whether Bt transgenic crops pose a threat to soil microorganisms, especially arbuscular mycorrhizal fungi. From the paper's abstract

Bt transgenic crops may affect AMF in many ways during their life with regard to the temporal-spatial relevance between the occurrence of Bt proteins and fungal symbiotic development of AMF. This may lead to an unwelcome surprise with regard to specific abundance and diversity of AMF when Bt transgenic crops are planted continuously. It is concluded that interactions between AMF and Bt transgenic crops at individual and community level are a new urgent soil ecological issue. Some evidence about Bt transgenic crop effects on AMF revealed by recent articles are summarized, and research prospects are highlighted in the paper.

Wenke, Liu and Du Lianfeng. 2008. Interactions between Bt transgenic crops and arbuscular mycorrhizal fungi: a new urgent issue of soil ecology in agroecosystems. Acta Agriculturae Scandinavica, Section B - Soil & Plant Science 58 (2) 187 - 192 DOI:10.1080/09064710701478339

Ecological Dimensions of Biofuels Conference

2008-01-29T14:10:00.000-06:00

The Ecological Society of America is sponsoring a conference on the Ecological Dimensions of Biofuels in Washington DC on March 10. Registration for the conference closes February 21. The conference website frames the issue:

Production of fuels from plants and agricultural and forestry wastes can reduce both society’s dependence on fossil fuels and net emissions of atmospheric carbon dioxide, the major contributor to global warming. Expanded use of this bioenergy requires assuring that its production and consumption are truly sustainable. This conference will explore the ecological dimensions of biofuels production and will identify management strategies and research opportunities to ensure their sustainability.

Some of the best writing on this issue can be found at Mike Palmer’s blog Low-Impact, High-Diversity Biofuels. Mike Palmer is an ecology professor at Oklahoma State University.

Predicting plant invasions

2008-01-29T14:07:00.000-06:00

In trying to identify potential invaders, most people tend to look for classic weeds. Species which mature quickly and produce large quantities of readily dispersed seed seem to be ideal candidates for invasion. However, actual studies of invasive species have shown them to be highly idiosyncratic - a non-native species that is invasive in one context may be benign in another context. In a paper published in the January issue of the Journal of Ecology, Angela Moles, Monica Gruber and Stephen Bonser have proposed a new framework for trying to identify potentially invasive plant species. [more]

Pitcher plant gives up its secret

2008-01-29T13:56:00.000-06:00

Pitcher plants use digestive enzymes to break down insects and use them as a nitrogen source. In a paper published in the Journal of Proteome Research, Naoya Hatano and Tatsuro Hamada used proteomic analysis to identify the full suite of enzymes that are present in pitcher fluid of Nepenthes alata. In addition to enzymes which break down proteins (which had been previously isolated) they found several proteins believed to inhibit bacterial growth.

Source: PhysOrg.com

Algae for food, fertiliser and fuel

2008-01-29T13:48:00.000-06:00

A profile of the Laboratory for Algae Research & Biotechnology (LARB) at Arizona State University’s Polytechnic Campus talks about the potential for algae for use as food, fertiliser and biofuel. Algae is being seen as a potential biofuel that does not compete with food for agricultural land. It can also be grown using agricultural wastes as a nitrogen source.

It sounds like a really interesting idea. Hopefully it won't be a cure that's worse than the disease...

Source: PhysOrg.com

Biocontrol for Australian invasive?

2008-01-29T13:41:00.000-06:00

Boneseed (Chrysanthemoides monilifera subsp. monilifera), one of Australia's "20 Weeds of National Significance" is the target of a biocontrol study using a rust fungus, Endophyllum osteospermi, that attacks it in its native range in southern Africa. The study is a collaboration between CSIRO in Australia and the Plant Protection Research Institute in Stellenbosch, South Africa.

Source: PhysOrg.com

Plant fungus affects sex ratios in parasitic wasp

2008-01-26T00:01:00.000-06:00

From PhysOrg.com

The study, recently published in the Proceedings of the Royal Society B, focused on the fungus (Podosphaera plantaginis), the plant (Plantago lanceolata), the checkerspot caterpillar (Melitaea cinxia) and the parasitoid wasp (Cotesia melitaearum) that share habitat in Åland, Finland.

The fungal endophyte alters leaf chemistry in the host plant. This slows the growth rate in Melitaea cinxia caterpillars that feed of the plant. The parasitoid wasp lays its eggs on the caterpillar; like other parasitoids, the wasp larvae gradually consume the still-living host. When the female wasp lays her eggs on caterpillars feeding on Podosphaera plantaginis plants, she ends up producing twice as many female as male offspring. A skewed sex ratio improves the success of these wasps in the fragmented habitat in which they live.